Integrasi Teknologi Koagulasi-Flokulasi dengan Filter Silika-Karbon Aktif Up Flow Sebagai Unit Pengolah Air Limbah Industri Karpet

Aris Mukimin; Agus Purwanto; Cholid Syahroni; Misbachul Moenir; Rame; Agung Budiarto

doi:10.21771/jrtppi.2017.v8.no1.p13-22

Authors

Aris Mukimin Balai Besar Teknologi Pencegahan Pencemaran Industri
Agus Purwanto Balai Besar Teknologi Pencegahan Pencemaran Industri
Cholid Syahroni Balai Besar Teknologi Pencegahan Pencemaran Industri
Misbachul Moenir Balai Besar Teknologi Pencegahan Pencemaran Industri
Rame Balai Besar Teknologi Pencegahan Pencemaran Industri
Agung Budiarto Balai Besar Teknologi Pencegahan Pencemaran Industri

DOI:

https://doi.org/10.21771/jrtppi.2017.v8.no1.p13-22

Keywords:

karpet, air limbah, lateks, koagulasi, karbon aktif

Abstract

Latek, kapur dan air merupakan bahan utama dalam proses produksi industri karpet. Komposisi dari ketiga bahan tersebut secara berurutan 30%, 50% dan 20% sehingga karakteristik air limbahnya dominan mengandung COD dan TDS. Integrasi koagulasi-flokuasi dengan filter silika-karbon aktif menjadi pilihan yang tepat sebagai unit pengolah polutan tersebut. Unit koagulasi dibuat dalam bentuk tabung silinder dengan kapasitas 2,5 m³, adapun filter silika-karbon aktif ditempatkan dalam dua tabung vertikal dengan kapasitas masing-masing 50 L . Proses koagulasi-fllokulasi dilakukan dengan sistem bacth menggunakan tawas dan anion yang dilanjutkan dengan sedimentasi dan aerasi. Filter vertikal silika-karbon aktif dioperasikan dengan sistem alir kontinyu secara up flow sebagai tahap akhir dari unit pengolahan. Reduksi COD dan DHL telah mampu mencapai 92% dan 74% dengan dosis tawas 1,96 Kg, kapur 0,857 Kg dan anion 1 g untuk volume limbah 2,45 m³ serta laju alir 6 L/menit di filter silika-karbon aktif.

References

Demmin TR., Uhrich KD., 1988, Improving carpet wastewater treatment, Andco Environmental Processes Inc, Amherst, New York

Dosta J., Rovira J., Gali A., Mace S., Mata-Alvarez J., 2008, Integration of a Coagulation/Flocculation step in a biological sequencing batch reactor for COD and nitrogen removal of supernatant of anaerobically digested piggery wastewater, Bioresource Technol 99: 5722-5730

Golob V., Vinder A., Simonic M., 2005, Efficiency of the coagulation/flocculation method for the treatment of dyebath effluents, Dye and Pigments 67: 93-97

Ahmad AL., Ismail S., Bhatia S., 2005, Optimization of coagulation-floculation process for plan oil mill effluent using response surface methodology, Environ Sci Technol 39: 2828-2834

Amuda OS., Alade A., 2006, Coagulation/flocculation process in the treatment of abattoir wstewater, Desalination 196: 22-31

Chang Q., Fu JY., Li ZL., 1993, Principles of flocculation, Lanzhou University Press, Lanzhou, China

Desjardins C., Koudjonou B., Desjardins R., 2002, Laboratory study of ballasted flocculation, Water Res 36: 744-754

Elmaleh S., Yahi H., Coma J., 1996, Suspended solids abatement by pH increase-upgrading of an oxidation pond effluent, Water Res 30: 2357-2362

Ghaly A., Snow A., Faber B., 2006, Treatment of grease filter wastewater by chemical coagulation, Canadian Bio Eng 48: 12-22

Gurses A., Yalcin M., Dogar C., 2003, Removal of remazol red RB by using Al(III) as coagulant-flocculant: effect of some variables on settling velocity, Water Air Soil Poll 146: 297-318

Hameed BH., Din ATM., Ahmad AL., 2007, Adsorption of methylene blue onto bamboo-based activated carbon: Kinetics and equilibrium studies, J Hazard Mater 141: 819-825

Harihastuti N., Djayanti S., Rame, 2016, Pengaruh waktu kontak terhadap daya adsorpsi karbon aktif pada pengembangan teknologi proses purifikasi biogas, Jurnal Riset Teknologi Pencegahan Pencemaran Industri 7: 57-65

Howe KJ., Marwah A., Chiu KP., Adham SS., 2006, Effect of coagulation on the size of MF and UF membrane foulants. Environ Sci Technol 40: 7908-7913

Hu C., Liu H., Qu J., Wang D., Ru J., 2005, Coagulation behavior of aluminum salts in eutrophic water: significance of Al13 species and pH control, Environ Sci Technol 40: 325-331

MetCalf dan Eddy, 1991, Wastewater engineering treatment, disposal and reuse, McGrow-Hill, New York

Meric S., Selcuk H., Belgionrno V., 2005, Acute toxicity removal in textile finishing wastewater by fenton’s oxidation, ozone and coagulation-flocculation processes, Water Res 39: 1147-1153

Miller SM., Fugate EJ., Craver VO., Smith JA., Zimmerman JB, 2008, Toward understanding the efficacy and mechanism of opuntia spp as a natural coagulant for potential application in water treatment, Environ Sci Technol 42: 4274-4279

Morales-Florez V., Santos A., Romero-Hermida I., Esquivias L., 2015, Hydration and carbonation reactions of calcium oxide by weathering: kinetics and changes in the nanostructure, Cheml Eng J 265: 194-200

Mukimin A., Vistanty H., Crisnaningtyas F., 2015, Physico-chemical treatment to enhanching electroactivity properties of coconute shell-based carbon electrode, Int J Appl Chem 11: 553-565

Nandy T., Shastry S., Pathe PP., kaul SN., 2003, Pre-treatment of currency printing ink wastewater through coagulation-flocculation process, water Air Soil Poll 148: 15-30

Quaissa YA., Chabani M., Amrane A., Bensmaili A., 2012, Integration of electro coagulation and adsorption for the treatment of tannery wastewater-the case of an Algerian factory Rouiba, Procedia Engineering 33: 98-101

Spicer PT., Pratsinis SE., 1996, Shear-induced Flocculation: the evalution of floc structure and the shape of the size distribution at steady state, Water Res 30: 1049-1056

Syu M., Chen B., Chou S., 2003, A study on the sedimentation model and neutral network online adaptive control of a benzoic acid imitated wastewater oxidation process. Ind Eng Chem Res 42: 6862-6871

Vistanty H., Mukimin A., Handayani NI., 2015, Pengolahan air limbah industri karton box dengan metode integrasi UASB dan elektrokoagulasi0flotasi, Jurnal Riset Teknologi Pencegahan Pencemaran Industri 6: 1-8

Wang DS., Tang HX., Gregory J., 2002, relative importance of charge neutralization and precipitation on coagulation of kaolin with PACl: effect of sulfate ion, Environl Sci Techn 36: 1815-1820

Wang JP., Chen YZ., Ge XW., Yu HQ., 2007, Optimization of coagulation-flocculation process for a paper-recycling wastewater treatment using respons e surface methodology, Colloids Surfaces A 302: 204-210

Wang JP., Chen YZ., Yuan SJ., Sheng GP., Yu HQ., 2009, Synthesis and characterization of a novel cationic chitosan-based flocculant with a high water-solubility for pulp mill wastewater treatment, Water Rese 43: 5267-5275

Wang JP., Chen YZ., Wang Y., Yuan SJ., Yu HQ., 2011, Optimization of the coagulation-flocculation process for pulp mill wastewater treatment using a combination of uniform design and response surface methodology, Water Res 45: 5633-5640

Zhu K., El-Din MG., Moawad AK., Bromley D., 2004, Physical and chemical processes for removing suspended solids and phosphourus from liquid swine manure, Environ Technol 25: 1177-1187