Preliminary Design of a Pressurized Liquid Extraction Unit for Phytochemicals Extraction
Subject Areas : PolymerAazam Sasani 1 , Abbas Rashidi 2
1 - Department of Chemical Engineering, Faculty of Technology and Engineering, University of Mazandaran
2 - Department of Chemical Engineering, Faculty of Technology and Engineering, University of Mazandaran
Keywords: Medicinal Plants, Bioactive compounds, Pressurized Liquid Extraction (PLE), Preliminary Design,
Abstract :
[1]. J.Azmir, I.S.M.Zaidul, M.M.Rahman, K.M.Sharif, A.Mohamed, F.Sahena, M.H.A.Jahurul,
K.Ghafoor, N.A.N.Norulaini, A.K.M.Omar, J. Food Eng., 117(4), 426 (2013).
[2]. M. Selvamuthukumaran, J. Shi, Food Qual. Saf., 1(1), 61 (2017).
[3]. M.B. Soquetta, L.D.M. Terra, C.P. Bastos, CyTAJ. Food, 16(1), 400 (2018).
[4]. K. Ameer, H.M. Shahbaz, J.H. Kwon, Compr. Rev. Food Sci. Food Saf., 16(2), 295 (2017).
[5]. Y.-F. Shang, K. Hyun Cha, E. Ha Lee, C.-H. Pan, B.-H. Um, Free Radicals Antioxid., 6(1), 64
(2015).
[6]. Z.Y. Ju, L.R. Howard, J. Agric. Food. Chem., 51(18), 5207 (2003).
[7]. A.P.D.F. Machado, J.L. Pasquel-Reátegui, G.F. Barbero, J. Martínez, Food Res. Int., 77, 675
(2015).
[8]. L. Howard, N.Pandjaitan, J. Food Sci., 73(3), C151 (2008).
[9]. S. Erdogan, B. Ates, G. Durmaz, I. Yilmaz, T. Seckin, Food Chem. Toxicol., 49(7), 1592
(2011).
[10]. Y. Jiang, S.P. Li, H.T. Chang, Y.T. Wang, P.F. Tu, J. Chromatogr. A, 1108(2), 268 (2006).
[11]. Z.A. Syahariza, A.E. Torkamani, H.M. Norziah, W.A.K. Mahmood, P. Juliano, Int. J. Food
Sci. Technol., 52(2), 480 (2017).
[12]. L. Foan, V. Simon, J. Chromatogr. A, 1256, 22 (2012).
[13]. A.D. Sousa, A.I.V. Maia, T.H.S. Rodrigues, K.M. Canuto, P.R.V. Ribeiro, R. de C.A. Pereira,
R.F. Vieira, E.S. de Brito,Ind. Crops Prod., 79, 91 (2016).
[14]. M.A. Rostagno, M. Palma, C.G. Barroso, Anal. Chim. Acta, 522(2), 169 (2004).
[15]. J. Hu, Z. Guo, M. Glasius, K. Kristensen, L. Xiao, X. Xu, J. Chromatogr. A, 1218(34), 5765
(2011).
[16]. J.L. Xu, T.J. Kim, J.-K. Kim, Y. Choi, Food Chem., 281, 261 (2019).
[17]. G. Zgórka, Talanta, 79(1), 46 (2009).
[18]. D.L. Luthria, J. Funct. Foods, 4(4), 842 (2012).
[19]. D.L. Luthria, Food Chem., 107(2), 745 (2008).
[20]. Y. Xu, F. Cai, Z. Yu, L. Zhang, X. Li, Y. Yang, G. Liu,Food Chem., 194, 650 (2016).
[21]. S. Mukhopadhyay, D.L.Luthria, R.J. Robbins, J. Sci. Food Agric., 86(1), 156 (2006).
[22]. H. Wu, M. Chen, Y. Fan, F. Elsebaei, Y. Zhu, Talanta, 88, 222 (2012).
[23]. D.T. Santos, P.C.Veggi, M.A.A.Meireles, J. Food Eng., 108(3), 444 (2012).
[24]. M. Søltoft, J.H. Christensen, J. Nielsen, P. Knuthsen, Talanta, 80(1), 269 (2009).
[25]. A.H.Zaibunnisa, S.Norashikin, S.Mamot, H.Osman, LWT Food Sci. Technol., 42(1), 233
(2009).
[26]. R.M. Alonso-Salces, A.Barranco, E.Corta, L.A.Berrueta, B. Gallo, F. Vicente,Talanta, 65(3),
654 (2005).
[27]. A. Mustafa, C. Turner, Anal. Chim. Acta, 703(1), 8 (2011).
[28]. M.S. Peters, K.D.Timmerhaus, R.E. West, Plant design and economics for chemical engineers,
McGraw-Hill, New York (2003).
[29]. B.E. Richter, B.A. Jones, J.L. Ezzell, N.L. Porter, N.Avdalovic, C.Pohl,Anal. Chem., 68(6),
1033 (1996).
[30]. A. Sae-Yun, C. Ovatlarnporn, A. Itharat, R. Wiwattanapatapee, J. Chromatogr. A, 1125(2),
172 (2006).
[31]. S. Koo, K. Cha, D. Song, D. Chung, C. Pan,J. Appl. Phycol., 24(4), 725 (2012).
[32]T.L.Miron, M. Plaza, G.Bahrim, E. Ibáñez, M. Herrero,J. Chromatogr. A, 1218(30), 4918
(2011).
[33]. Y.F. Shang, S.M. Kim, B.-H. Um, Food Chem., 154, 164 (2014).
[34]. R.B. Carl, Rules of Thumb for Chemical Engineers, Gulf Publishing Company, USA (1998).
[35]. E.E. Ludwig, Applied Process Design for Chemical and Petrochemical Plants: Volume 2, Gulf
Professional Publishing, USA (1997).
[36]. C. Pronyk, G. Mazza, J. Food Eng., 95(2), 215 (2009).
[37]. R. Turton, R.C. Bailie, W.B. Whiting, J.A. Shaeiwitz, D. Bhattacharyya, Analysis, Synthesis
and Design of Chemical Processes. Pearson Education, USA (2008).
[38]. S. Hall, Rules of Thumb for Chemical Engineers. Butterworth-Heinemann, USA (2017).
[39]. M.N. Shatla, M. El Hady, Storage Tanks-Selection of Type, Design Code and Tank Sizing.
International conference of chemical engineering; Cairo (Egypt) (2004).
[40]. W. Tipasri, T.Wongwuttanasatian, Energy Procedia, 156, 254 (2019).
[41]. W.B. Glover, Chem. Eng. Prog., 100(12), 26 (2004).
[42]. G.Saravacos, A.E.Kostaropoulos, Handbook of food processing equipment, Springer,
Switzerland (2002).
[43]. H. Chen, Factors affecting heat transfer in the falling film evaporator. A thesis presented in
partial fulfillment of the requirements for the degree of Master of Technology in Food Technology
at Massey University. Massey University (1992).
[44]. Z.I. Stefanov, Fundamental modeling and control of falling film evaporators. PhD Thesis in
Chemical Engineering. Texas Tech University (2004).
[45]. A. Prakash, C. Patil, S.Vinodhini, A.Panneerselvam, V.D. Rajeswari, Engineering Approach in
Beverage Industry, in Engineering Tools in the Beverage Industry, Elsevier (2019).
[46]. E.S. Ong, S.M. Len, J. Chromatogr. Sci., 42(4), 211 (2004).
[47]. E.S. Ong, S.M. Len, Anal.Chim. Acta, 482(1), 81 (2003).
[48]. E.S. Ong, J. Sep. Sci., 25(13), 825 (2002).
[49]. N.Y. Qin, F.Q. Yang, Y.T. Wang, S.P. Li, J. Pharm. Biomed. Anal., 43(2), 486 (2007).
[50]. I.C.N. Debien, R. Vardanega, D.T. Santos, M.A.A. Meireles, Sep. Sci. Technol., 50(11), 1647
(2015).
[51]. R.M. Alonso-Salces, E. Korta, A. Barranco, L.A. Berrueta, B. Gallo, F. Vicente, J. Agric. Food
Chem., 49(8), 3761 (2001).
[52]. B. Benthin, H.Danz, M. Hamburger, J.Chromatogr. A, 837(1-2), 211 (1999).
[53]. E.-S. Ong, S.-O. Woo, Y.-L. Yong, J. Chromatogr. A, 904(1), 57 (2000).
[54]. A.P. da Fonseca Machado, C.A. Rezende, R.A. Rodrigues, G.F. Barbero, P. de Tarso Vieira e
Rosa, J. Martínez, Powder Technol., 340, 553 (2018).
[55]. A.G. da Silva Carvalho, M.T. da Costa Machado, V.M. da Silva, A. Sartoratto, R.A.F.
Rodrigues, M.D. Hubinger, Powder Technol., 294, 421 (2016).
[56]. Y.R.R.S. Rezende, J.P. Nogueira, N.J.F.C.Narain, Food Chem., 254, 281(2018).
[57]. E.Eroğlu, İ.Tontul, A.Topuz, J. Food Process. Preserv., 42(6), e13643 (2018).
[58]. M.E. Sormoli, T.A.G.Langrish, Innovative Food Sci. Emerg. Technol., 37(A), 27 (2016).
[59]. E. L. doCarmo, R.A.R. Teodoro, P.H.C. Félix, R.V. de BarrosFernandes, É. R. deOliveira,
T.R.L.A. Veiga, S. V. Borges, D.A. Botrel, Food Chem., 249, 51 (2018).
[60]. M.C.R. Salas, H.J.C.Velásquez, J.H.G. Gonzalez, Powder Technol., 321, 163 (2017).
[61]. C. Yamashita, M.M.S. Chung, C. dos Santos, C.R.M. Mayer, I.C.F. Moraes, I.G. Branco, LWT,
84, 256 (2017).
[62]. L.T.Chaul, E.C.Conceição, M.T.F.Bara, J.R.Paula, R.O.Couto, Revista Brasileira de
Farmacognosia, 27(2), 236 (2017).
[63]. T. Kuppan, Heat Exchanger Design Handbook, Marcel Dekker, Inc (2000).
[64]. M. Nitsche, R.O.Gbadamosi, Heat Exchanger Design Guide: A Practical Guide for Planning,
Selecting and Designing Shell and Tube Exchangers. Butterworth-Heinemann (2015).
[65]. H.S. Lee, Thermal Design: Heat Sinks, Thermoelectrics, Heat Pipes, Compact Heat
Exchangers, and Solar Cells, John Wiley & Sons (2010).
[66]. G. Towler, R. Sinnott, Chemical Engineering Design: Principles, Practice and Economics of
Plant and Process Design. Elsevier (2012).
[67]. S. Rodríguez-Rojo, Antioxidants, 10(10), 1568 (2021).
[68]. Z. Mrkonjic, D. Rakic, M. Kaplan, N. Teslic, Z. Zekovic, B. Pavlic, Molecules, 26, 2548
(2021).
