Nashrieh Shimi va Mohandesi Shimi Iran

Nashrieh Shimi va Mohandesi Shimi Iran

Liquefaction of Lignocellulosic Wastes by Using Ethylene Carbonate Solvent: The Effect of Process Variables on Properties

Document Type : Research Article

Authors
Soheyla Daneshvar 1
Rabi Behrooz 1
Saeed Kazemi Najafi 1
Gity Mir Mohamad Sadeghi 2
1 Faculty of Natural Resources and Marine Sciences, Tarbiat Modares University (TMU), Noor, I.R. IRAN
2 Polymer Engineering and Color Technology Department, Amirkabir University of Technology, Tehran, I.R. IRAN
Abstract
Ethylene Carbonate (EC) was selected as a new solvent in order to establish a rapid liquefaction technique converting lignocellulosic waste into useful chemicals. Beechwood sawdust was liquefied by using Ethylene Carbonate (EC) as a solvent and sulfuric acid as a catalyst at high temperatures (110-160°C) and at three times (20, 40, 60 minutes) for the preparation of suitable polyol. After the liquefaction process at different temperatures and times and investigation of characterization of hydroxyl number, acid number, and yield of polyol were seen that the temperature of 130°C was an appropriate temperature for the production of polyol. Then in order to determine the appropriate time for producing the polyol at this temperature, the liquefaction process was continued at different times (40, 60, 90, 120, and 180 min) which as a result 120 minutes being selected as an appropriate time for the preparation of polyol. Also, the results showed that with increasing the temperature and time of liquefaction, the acid number and yield, and viscosity were increased, but hydroxyl number was reduced. The FTIR spectroscopy analysis showed the existence of the hydroxyl groups (OH) in the liquefied Beech sawdust (polyol) and confirmed that wood sawdust is a source of bio polyols. Also, it can be concluded that bio polyol is suitable for the preparation of polymeric products, including polyurethane adhesive. Statistical analysis showed that variation of hydroxyl and acid number, yield, and viscosity have a significant difference with increasing at temperature and time.
Keywords
Ethylene carbonate
Liquefaction process
Beechwood sawdust
Bio Polyol

Subjects

[1] Aniceto P.S., Portugal I., Silva C.M., Biomass-Based Polyols through Oxypropylation Reaction, J. Chem. Sus. Chem, 5(8): 1358-1368 (2012).
[2] Barnésa M.C., Vissera M.M., Rossumb G., Kerstena S.R.A., Langea J. P., Liquefaction of Wood and its Model Components, Anal Appl Pyrol, 125(1): 136–143 (2017).
[3] Bodirlau R., Teaca, C.A., Fourier Transforms Infra-Red Spectroscopy and Thermal Analysis of Lignocellulose Fillers Treated with Organic Anhydrides, Rom. Journ. Phys, 54(1-2): 93–104 (2009).
[4] D’Souza J., Yan N., Producing Bark-based Polyols through Liquefaction: Effect of Liquefaction Temperature, ACS Sustainable Chem. Eng, 1(1): 534–540 (2013).
[5] Fierz-David  H.E.,. The Liquefaction of Wood and Some General Remarks on the Liquefaction of Coal, Chem. Indust. Rev, 44: 942–944(1925).
[6] Elliott D.C., Biller P., Ross A.B., Schmidt A.J., Jones S.B., Hydrothermal Liquefaction of Biomass: Developments from Batch to Continuous Process, Bioresour. Technol., 178(1): 147–156 (2015).
[7] Gollakota A.R.K., Kishoreb N., Gua S., A review on Hydrothermal Liquefaction of Biomass, Renew Sustain Energy Rev, 81(1): 1378-1392(2018).
[8] Hassan E.M., Shukry N., Polyhydric Alcohol Liquefaction of Some Lignocellulosic Agricultural Residues, Industrial Crops and Products, 27(1): 33–38(2008).
[9] Hu S., Luo X., Li Y., Polyols and Polyurethanes from the Liquefaction of Lignocellulosic Biomass, Department of Food, Agricultural and Biological Engineering. J. Chem. Sus. Chem, 7(1): 66–72 (2014).
[10] Juhaida M.F., Paridah M.T., Hilmi M.M., Sarani Z., Jalaluddin H., Mohamad Zaki A.R., Liquefaction of Kenaf (Hibiscus cannabinus L.) Core for Wood Laminating Adhesive, Biores. Technol, 101(4): 1355–1360 (2010).
[11] Kong X., Liu G., Curtis G.M., Characterization of Canola Oil Based Polyurethane Wood Adhesives, Int. J. Adhes & Adhes, 31(6): 559–564 (2011).
[12] Kosmela P., Hejna A., Formela K., Haponiuk J.T., Piszczyk L., Biopolyols Obtained Via Crude Glycerol-Based Liquefaction of Cellulose: Their Structural, Rheological and Thermal Characterization, Cellulose, 23(5): 2929–2942 (2016).
[13] Kunaver M., Jasiukaityte E., Cuk N., Guthrie J.T., Liquefaction of Wood, Synthesis and Characterization of Liquefied Wood Polyester Derivation, J. Appl. Polym. Sci, 115(3): 1265-1271 (2010).
[14] Lee W.J., Lin M.S., Preparation and Application of Polyurethane Adhesives Made from Polyhydric Alcohol Liquefied Taiwan Acacia and China Fir, Appl Polym Sci, 109(1): 23-31(2008).
[15] Leite B.S., Figueiredoa T. D., Leitea A. F., Carriçob C. S., Pasab M. D., Polyol and Foam Production from Lemon Bagasse Liquefaction, Chemical Engineering Transactions, AIDIC Servizi S.r.l, 65(1): 1-6 (2018).
[16] Meilan A. C., Goodman, A., Baron, M., Rodriguez, J. G., An Specific case in the Classification of Woods by FTIR and Chemo Metrics: Discrimination of Fagales from Malpighiales, J. Cellulose, 21(1): 261-273 (2014).
[17] Mori R., Inorganic–Organic Hybrid Biodegradable Polyurethane Resin Derived From Liquefied Sakura Wood, Wood Sci. Technol, 49(3):507-516 (2015).
[18] Ono H., YamadaT., HatanoY., MotohashiK., Adhesives from Waste Paper by Means of Phenolation, J. Adhes,59(1-4): 135- 145 (1996).
[19] Pan H., shupe T.F., Hse C.Y., Characterization of Liquefied Wood Residues from Different Liquefaction Conditions, J. Appl. Polym. Sci,105(6): 3739-3746 (2007).
[20] Pu S., Shiraishi N., Liquefaction of Wood Without a Catalyst I. Time Course of Wood Liquefaction with Phenols and Effects of Wood/Phenol Ratios, Mokuzai Gakkaishi, 39(4): 446-452 (1993).
[21] Rastegarfar N., Behrooz R., Barikani M., Characterization of Polyurethane Foams Prepared from Liquefied Sawdust by Crude Glycerol and Polyethylene Glycol, Polym.Res., 25:154-162 (2018).
[22] Riddick J.A., Bunger W.B., Sakano T.K., "Organic Solvents, Physical Properties and Methods of Purification", 4th ed., Wiley, John & Sons, Inc., New York (1986).
[23] "Standard Test Methods for Testing Polyurethane Raw Materials: Determination of Acidity as Acid Number of Polyols", Annual Book of ASTM Standard, D 4662-08 (2012).
[24] "Standard Test Methods for Testing Polyurethane Raw Materials: Determination of Hydroxyl Numbers of Polyols", Annual Book of ASTM Standard, ASTM D 4274-05D (2012).
[25] "Standard Test Methods for Testing Polyurethane Raw Materials: Determination of Viscosity of Polyols", Annual Book of ASTM Standard, ASTM D 4878-08 (2012).
[26] Yamada T., Ono H., Rapid Liquefaction of Lignocellulosic Waste by Using Ethylene Carbonate, Biores. Technol., 70(1): 61-67 (1999).
[27] Yao Y., Yoshioka M., Shiraishi N., Combined Liquefaction of Wood and Starch in a Polyethylene Glycol/Glycerin Blended Solvent, Mokuzai Gakkaishi(JWRS), 39: 930–993 (1993).
[28] Yao Y., Yoshioka M., Shiraishi N., Water-Absorbing Polyurethane Foams from Liquefied Starch, J. Appl. Polym. Sci, 60(11): 1939–1949 (1996).
[29] Yue D., Oribayo O., Rempel G.L., Pan O., Liquefaction of Waste Pine Wood and its Application in the Synthesis of Flame Retardant Polyurethane Foam, RSC Adv, 7(1): 30334–30344 (2017).
[30] Zhang H. R., Ding F., Luo C. R., Xiong L., Chen X. D., Liquefaction and Characterization of Acid Hydrolysis Residue of Corncob in Polyhydric Alcohols, Indus. Crop. Prod,39(1): 47–51 (2012).
[31] Zhang H., Luo J., Li  Y., Guo H., Xiong L., Chen  X., Acid-Catalyzed Liquefaction of Bagasse in the Presence of Polyhydric Alcohol, J. Appl. Biochem. Biotechnol, 170(7): 1780-1791(2013).
[32] Zhang H., Yang H., Guo H., Huang C., Xiong L., Chen X., Kinetic Study on the Liquefaction of Wood and its Three Cell Wall Component in Polyhydric Alcohols, Appl. Energy, 113: 1596–1600(2014).
[33] Zhang Z., Harrison M. D., Rackemann D.W., Doherty W.O.S., O’Hara I.M., Organosolv Pretreatment of Plant Biomass for Enhanced Enzymatic Saccharification. Green Chem., 18(2): 360-381 (2016).