Biodiesel Production using Oil Extracted from Cooling Pond Wastewater with Esterification of Sulfonated Carbon Catalyst and Transesterification of Na2CO3 Catalyst

Kolakaningrum, Chandra Fitri; Agustina, Tuty Emilia; Hadiah, Fitri

doi:10.12911/22998993/142186

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Tytuł artykułu

Biodiesel Production using Oil Extracted from Cooling Pond Wastewater with Esterification of Sulfonated Carbon Catalyst and Transesterification of Na2CO3 Catalyst

Autorzy

Kolakaningrum Chandra Fitri , Agustina Tuty Emilia , Hadiah Fitri

Treść / Zawartość

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6_kolakaningrum_biodiesel_jee_10_2021.pdf

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DOI

10.12911/22998993/142186

Warianty tytułu

Języki publikacji

Abstrakty

While high production of palm oil improves the community economy, it has the potential to damage the environment because it produces the waste containing quite a lot of residual oil. The wastewater generated by this production process flows into the cooling pond before it is further processed in aerobic and anaerobic ponds. The residual oil contained in the cooling pond can be collected and used, e.g. as raw material for biodiesel production. This research aimed to produce biodiesel by utilizing the oil extracted from cooling pond wastewater through the esterification method with a sulfonated carbon catalyst and a transesterification method with the Na₂CO₃ catalyst. The sulfonated carbon catalyst was made from the palm kernel shells as a solid waste of the palm oil plant. In order to study the optimum amount of catalyst usage, the catalyst ratio was varied, i.e. 8–16% for the esterification process and 1–3% for the transesterification process. The reuse performance of sulfonated carbon catalysts was varied three times. On the basis of the research results, sulfonated carbon catalysts were proven to be effective as heterogeneous catalysts in the esterification process because they can reduce acid level to below 5 mg KOH/g oil. The sulfonated carbon catalyst ratio of 12% was the optimum ratio which can reduce the acid level to 4.62 mg KOH/g oil. The reuse of sulfonated carbon can reduce the acid level to 6.9 mg KOH/g oil at the first reuse. In the transesterification process, the optimum ratio of the Na₂CO₃ catalyst of 3% was found. The biodiesel produced has met the biodiesel characteristics of National Indonesian Standard (SNI of 7182:2015) with the saponification number of 197.18 mg KOH/g oil, free glycerol of 0.09%, FAME content of 96.79%, and density of 886 kg/m³.

Słowa kluczowe

cooling pond wateswater esterification transesterification sulfonated carbon Na2CO3 sodium carbonate biodiesel

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2021

Tom

Vol. 22, nr 10

Strony

51--62

Opis fizyczny

Bibliogr. 31 poz., rys., tab.

Twórcy

autor

Kolakaningrum Chandra Fitri

Master Program of Chemical Engineering, Environmental Technology, Universitas Sriwijaya, Jl. Srijaya Negara, Bukit Besar, Palembang 30139, South Sumatera, Indonesia

autor

Agustina Tuty Emilia

tuty_agustina@unsri.ac.id

Chemical Engineering Department, Faculty of Engineering, Universitas Sriwijaya, Jl. Raya Palembang-Prabumulih Km. 32 Indralaya, Ogan Ilir 30662, South Sumatera, Indonesia

https://orcid.org/0000-0002-7289-7318

autor

Hadiah Fitri

Chemical Engineering Department, Faculty of Engineering, Universitas Sriwijaya, Jl. Raya Palembang-Prabumulih Km. 32 Indralaya, Ogan Ilir 30662, South Sumatera, Indonesia

Bibliografia

1. Abdelrahman B.F., Aziz A.M., Al-Tamer M.H. 2016. Biodiesel Production from Silybum Marianum L. Seed Oil with High FFA Content using Sulfonated Carbon Catalyst for Esterification and Base Catalyst for Transesterification. Journal of Energy Conversion and Management, 108, 255–265.
2. Agustina T.E., Chandra I.M., Nopriyansyah M., Arita S., Hadiah F., Sari T.I., Prakoso T., Heraldy E. 2019. The Extraction of Oil From Cooling Pond Wastewater as A Raw Material for Biodiesel. IOP Conference Series: Materials Science and Engineering, 845(1), 1–9.
3. Amelia C., Andini P., Adhiwardana S., Prasetyani T., Budiastuti H., Widarti S. 2017. Oxidative Resistance and Physical Properties from Palm Fatty Acid Distillate (PFAD) using Antioxidant X. Proceedings of the National Seminar on Chemical Industry Process Engineering, 1, 20–26.
4. Badan Standarisasi Nasional (BSN). 2015. Standar Nasional Indonesia (SNI) 7182: Biodiesel.
5. Balan W.S., Janaun J., Chung C.H., Zhu Z., Haywood S.K., Touhami, D., Chong, K.P., Yaser A.Z., Lee P.C., Zein S.H. 2020. Esterification of Residual Palm Oil Using Solid Acid Catalyst Derived from Rice Husk. Journal of Hazardous Materials, 20, 10–20.
6. Chanakaewsomboon I., Tongurai C., Photaworn S., Kungsanant S., Nikhom R. 2019. Investigation of Saponification Mechanisms in Biodiesel Production: Microscopic Visualization of the Effects of FFA, Water, and the Amount OF Alkaline Catalyst. Journal of Environmental Chemical Engineering. S2213–3437(19)30661-X.
7. Dalimunthe I.S., Restuhadi F., Efendi R. 2016. Synthesis of Biodiesel from Used Cooking Oil using Heterogenous Catalyst Based on Chicken Eggshells. Agricultural Science Journal, 3(2), 1–6.
8. Furqon F., Nugroho A.K., Anshorulloh M.K. 2019. Study of KOH Catalyst in Biodiesel Production using Batch Reverse Flow Biodiesel Reactor. Journal of Hue Agricultural Engineering, 12(1), 22–31.
9. Haryono, Rahayu, I., Yulyati Y.B. 2016. Biodiesel from Used Palm Oil Cooking Oil with CaO Heterogeneous Catalyst: Study of Determination of Mol Ratio of Oil/Methanol and Optimal Reaction Time. Exergy Journal, 13(1), 1–5.
10. Hidayat N., Wahab A., Marlina E. 2019. The Effect of CaO Catalyst on the Production Biodiesel from Jatropa Oil with Transesterification Process. Engineering Journal, 12(1), 15–20.
11. Husin H., Mahidin, Marwan. 2011. Study of Using Catalysts of Coconut Coir Ash, Palm Bunch Ash, and K2CO3 for Converting Castor Oil to Biodiesel. Reaktor Journal, 13(4), 254–261.
12. Kusumawardani D.S., Agustina T.E., Siddik M.A.B. 2019. Utilization of Palm Oil Wastewater as Raw Material Alternative for Transformer Oil. Indonesia Journal of Fundamental and Applied Chemistry, 5(2), 54–58
13. Laila L. & Oktavia L. 2017. Study Experiments on Free Fatty Acid and Viscosity of Biodiesel Palm Oil Based from PT. Smart Tbk. Journal of Process Technology and Industrial Innovation, 2(1), 27–31.
14. Maisarah S., Manurung R., Alhamdi M.A., Syahputra A., Ramadhani D.A. 2017. Degummed Palm Oil Methanolysis Process Using Choline Chloride (ChCl) and Glycerol Based Deep Eutectic Solvent (DES) as Co-solvent at Biodiesel Production. International Conference on Sustainable Energy Engineering and Application, 6(10), 128–132.
15. Malins K. 2018. The Potential of K3PO4, K2CO3, Na3PO4, and Na3CO3 as reusable alkaline catalysts for pratical application in Biodiesel Production. Journal of Fuel Processing Technology, 179, 302–312.
16. Mantovani S.A. 2020. The Effect of Catalyst Mass dan Reaction Time on the Conversion of Biodiesel from Used Cooking Oil with CaO Catalyst from Eggshells. Industrial Engineering Scientific Journal, 19(2), 212–222.
17. Nata I.F., Putra M.D., Irawan C., Lee C.K. 2017. Catalytic Performance of Sulfonated Carbon-Based Solid Acid Catalyst on Esterification of Waste Cooking Oil for Biodiesel Production. Journal of Environmental Chemical Engineering, 5, 2171–2175,
18. Ngaosuwan K., Goodwin J.G., Prasertdham P. 2016. A Green Sulfonated Carbon-based Catalyst derived from Coffee Residue for Esterification. Journal of Renewable Energy, 86, 262–269.
19. Ni Z., Li F., Wang H., Wang S., Gao S. 2019. Catalyst Esterification, Kineticts, and Cold Flow Properties of Isobutyl Palmitate. Journal of Fuel, 254, 115368.
20. Ningsih S.H. 2015. The Effect of Glycerol Plasticizer on Characteristics of Mixed Edible Film from Whey and Jelly. Fundamental and Applied Reasearch on Industrial Engineering Journal, 7(1), 12–20.
21. Nirwana & Irdoni. 2004. Preliminary Study of Synthesis of Polyester from Palm Oil Raw Materials. International Journal of Science and Applied Technology, 10, 45–57.
22. Niu S., Ning Y., Lu C., Han, K., Yu H., Zhou Y. 2018. Esterification of Oleic Acid to Produce Biodiesel Catalyzed by Sulfonated Activated Carbon from Bamboo. Journal Energy Conversion and Management, 163, 59–65.
23. Nuryanti R., Agustina T.E., Sari T.I. 2019. The Utilization of Palm Oil Mill Effluent for Renewable Energy. Indonesia Journal of Fundamental and Applied Chemistry, 4(3), 116–121.
24. Otera J. & Nishikido J. 2009. Esterification: Methods, Reactions, and Application. Wiley-VCH, German.
25. Prihanto A. & Irawan T.A.B. 2017. The Effect of Temperature, Catalyst Concentration, and Methanol-Oil Ratio on Biodiesel Yield from Used Cooking Oil through Neutralization-Transesterification Process. Methane Journal, 13(1), 30–36.
26. Sangar K.S., Lan C.S., Razali S.M., Farabi M.S., Taufiq Y.H. 2019. Methyl Ester Production from Palm Fatty Acid Distillate (PFAD) using Sulfonated Cow Dung-derived Carbon based Solid Acid Catalyst. Journal of Energy Conversion and Management, 196, 1306–1315.
27. Sani Y.M., Daud W.M.A.W., Aziz A.R.A. 2014. Activity of Solid Acid Catalysts for Biodiesel Production: A Critical Review. Applied Catalysis A: General Review, 470, 140–161.
28. Saputra D.A. & Triyono. 2013. Synthesis and Characterization of MgO/I3-Alumina Catalysts for Transesterification of Castor Oil (Ricinus Communis) into Biodiesel. Process Engineering Journal, 11(3), 30–42.
29. Susilawati & Supijatno. 2015. Oil Palm Waste Management, Riau. Newsletter of Argonomy Horticulture, 3(2), 203–212.
30. Wahyuni S., Ramli, Mahrizal. 2015. The Effect of Process Temperature and Deposition Time on the Quality of Biodiesel from Used Cooking Oil. Pillar of Physics. 6(10), 33–40.
31. Yusuf M. 2018. Determination of Free Fatty Acid and Saponification Number at PT. Oil Palm Research Center, Medan. Sustainable Cities and Society Journal, 41, 220–226

Typ dokumentu

Bibliografia

Identyfikator YADDA

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