Sustainable Treatment of Domestic Sullage through Utilization of Garcinia mangostana pericarp extract as Natural Coagulant
Paper Details
Sustainable Treatment of Domestic Sullage through Utilization of Garcinia mangostana pericarp extract as Natural Coagulant
Abstract
This paper presented the potential of Garcinia mangostana as a natural coagulant in the removal of selected water quality parameters, namely: turbidity, total suspended solids, and biochemical oxygen demand from domestic sullage generated by the University of Science and Technology of Southern Philippines. The jar test method is used in the optimization of the coagulants and lab analysis uses the gravimetric method, dilution technique, and digital meter for the measurements of the parameters. Characterization of Garcinia mangostana revealed a possible functional group that influences coagulation activity. Optimization of pure Garcinia mangostana using the jar test method showed the highest efficiency removal for the selected water parameters at 50 mg/L and pH9. Using the optimum dosage of 50 mg/L, the optimum settling time was 90 minutes for the treatments of A100, M100, A50M50, A25M75 & A75M25. The highest removal percentage was at pH9 for turbidity at 93.25% (A50M50), TSS removal was 93.32% at A50M50, whilst percent BOD removal was 92.12% (A75M25). Statistical evidence showed significant differences in the measured values among treatment designs with optimum doses. To investigate the influence of mixing intensity, settling rate, contact time, and other variables are suggested for future studies to help improve removal efficiency.
Amuda OS, Amoo IA. 2006. Coagulation/flocculation process and sludge conditioning in beverage industrial wastewater treatment. Journal of Hazardous Materials 141(3), 778-783.
Anastasakis K, Kalderis D, Diamadopoulos E. 2009. Flocculation behavior of mallow and okra mucilage in treating wastewater. Desalination, 249(2), 786-791.
Boulaadjoul, Soumia, Hassiba Zemmouri, Zoubida Bendjama, Nadjib Drouiche. 2018. “A novel use of Moringa oleifera seed powder in enhancing the primary treatment of paper mill effluent. “Chemosphere 206, 142-149.
Chen Y, Mingjie Huang, Weiqun Chen, Biao Huang. 2012. Adsorption Of Cu(Ii) From Aqueous Solution Using Activated Carbon Derived From Mangosteen Peel. Bio Resources 7(4).
Choy SY, Prasad KMN, Wu TY, Ramanan RN. 2015. A review on common vegetables and legumes as promising plant-based natural coagulants in water clarification. International Journal of Environmental Science and Technology 12, 367–390.
Ferreira PC, Piai KDA, Takayanagui AMM, Segura-Muñoz SI. 2008. Aluminum as a risk factor for Alzheimer’s disease. Revista latino-americana de enfermagem 16(1), 151-157.
Huang X, Bo X, Zhao Y, Gao B, Wang Y, Sun S, Li Q. 2014. Effects of compound bioflocculant on coagulation performance and floc properties for dye removal. Bioresource technology 165, 116-121.
Ismail IM, Fawzy AS, Abdel-Monem NM, Mahmoud MH, El-Halwany MA. 2012. Combined coagulation flocculation pre- treatment unit for municipal wastewater. Journal of Advanced Research 3(4), 331-336.
Jain RK, Dange PS, Lad RK. 2015. A treatment of domestic sewage and generation of bio sludge using natural coagulants. IJRET journal 4(7), 152-156.
Kellner R, Kuhnert-Brandstätter M, Malissa H. 1988. FTIR-Microscopic investigations of micro-phases and micro-phase-transitions in organic substances. Microchimica Acta, 96(1-6), 153-165.
Kilobe BM, Mdegela R, Mtambo MM. 2013. Acceptability of wastewater resource and its impact on crop production in Tanzania: The case of Dodoma, Morogoro and Mvomero wastewater stabilization ponds. Kivukoni Journal 1(2), 94–103.
Kim DS, Hong SB, Kim YJ, Lee KW. 2006. Deposition and coagulation of polydisperse nanoparticles by Brownian motion and turbulence. Journal of aerosol science 37(12), 1781-1787.
Malakoutian M, Fatehizadeh A. 2010. Color removal from water by coagulation/caustic soda and lime.
Martyn CN, Barker DJP, Osmund C, Harris E C, Edwardson JA, Lacey RF. 1989. Geographical relation between Alzheimer’s disease and aluminium in drinking water. Lancet, 333, 59–62.
Metcalf EAT, Burton FL, Leverenz HL, Tsuchihashi R, Tchobanoglous G. 2006. Water reuse: issues technologies, and applications. 1st ed. New York: McGraw-Hill; 2006.
Okuda T, Baes AU, Nishijima W, Okada M. 2001. Coagulation mechanism of salt solution-extracted active component in Moringa oleifera seeds. Water Res 35(3), 830–834.
Pedraza-Chaverri J, Cárdenas-Rodríguez N, Orozco-Ibarra M, Pérez-Rojas JM. 2008. Medicinal properties of mangosteen (Garcinia mangostana). Food and chemical toxicology 46(10), 3227-3239.
Radoiu MT, Martin DI, Calinescu I, Iovu H, 2004. Preparation of polyelectrolytes for wastewater treatment. Journal of Hazardous Materials 106, 27-37.
Renault F, Sancey B, Charles J, Morin-Crini N, Badot PM, Winterton P, Crini G. 2009. Chitosan flocculation of cardboard-mill secondary biological wastewater Chemical Engineering Journal 155, 775-783.
Shon HK, Vigneswaran S, Snyder SA. 2006. Effluent Organic Matter (EfOM) in Wastewater: Constituents, Effects, and Treatment, Critical Reviews in Environmental Science and Technology 36(4), 327-374. http://dx.doi.org/10.1080/10643380600580011
Sriyanti I, Dhewa Edikresnha AR, Munir MM, Rachmawati H, Khairurrijal K. 2018. Mangosteen pericarp extract embedded in electrospun PVP nanofiber mats: physicochemical properties and release mechanism of α-mangostin. International journal of nanomedicine 13, 4927.
Suttirak W, Manurakchinakorn S. 2014. In vitro antioxidant properties of mangosteen peel extract. Journal of food science and technology 51(12), 3546-3558.
Telles DDA, Costa RP. 2010. Water Reuse: Concepts, theories and practices.-2nd Ed. Sao Paulo, Biucher Ed, pg. 311.
Theodoro JDP, Lenz GF, Zara RF, Bergamasco R. 2013. Coagulants and Natural Polymers: Perspectives for the Treatment of Water, Plastic and Polymer Technology 2(3), 55-62.
Ugonabo VI, Menkiti MC, Onukwuli OD. 2012. Coagulation kinetics and performance evaluation of corchorus olitorus seed in pharmaceutical effluent, International Journal of Multidisciplinary Science and Engineering 3(7), 20-32.
Ugwu SN, Umuokoro AF, Echiegu EA, Ugwuishiwu BO, Enweremadu1 CC. 2017. Comparative study of the use of natural and artificial coagulants for the treatment of sullage (domestic wastewater). Cogent Engineering 4, 1365676.
Wathoni N, Shan CY, Shan WY, Rostinawati T, Indradi RB, Pratiwi R, Muchtaridi M. 2019. Characterization and antioxidant activity of pectin from Indonesian mangosteen (Garcinia mangostana L.) rind. Heliyon, 5(8), e02299.
Zhang X, Yang Z, Wang Y, Gao, BY, Yue Q. 2012. The removal efficiency and reaction mechanism of aluminum coagulant on organic functional groups-carboxyl and hydroxyl, Chemical Engineering Journal 211–212, 186–194.
Zhang J, Zhang F, Luo Y, Yang H. 2006. A preliminary study on cactus as coagulant in water treatment. Process biochemistry 41(3), 730-33.
Zonoozi MH, Moghaddam MRA, Arami M. 2008. Removal of acid red 398 dye from aqueous solutions by coagulation/flocculation process. Environmental Engineering and Management Journal 7(6), 695-699.
Gina C. Lacang (2023), Sustainable Treatment of Domestic Sullage through Utilization of Garcinia mangostana pericarp extract as Natural Coagulant; IJB, V22, N2, February, P120-134
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