Politeknik Negeri Lampung - Indonesia
Industrial wastewater treatment using venture injector type Micro-bubble aeration as a reduction of dissolved Iron (Fe2+) levels
Water quality problems that are often encountered, especially by-product wastewater resulting from industrial processes that do not meet the requirements for wastewater quality standards. Iron levels in wastewater can cause the water to turn brownish yellow and produce an unpleasant odor, which of course has a big impact on the environment. Therefore, it is necessary to implement a treatment process to reduce the iron level in the water, ensuring that the water is safe when discharged into the environment. The purpose of this research is to analyze the initial parameters of temperature, pH, TDS, TSS, dissolved oxygen (DO) and dissolved iron (Fe2+) in industrial waste water and then wanted to know whether the venture injector type micro bubble aeration process was able to increase the value of dissolved oxygen (DO) and decrease the dissolved iron content (Fe2+) in wastewater and to know the micro bubble type aeration process Venture injectors are the best to use. The research was conducted with an experimental design using a completely randomized design (RAL) with two factors: air flow (2 LPM, 4 LPM, and 6 LPM) and aeration time (0 minutes, 15 minutes, 30 minutes, 45 minutes, and 60 minutes), each with two repetitions. In the results of the initial parameter analysis, the pH value was 8.02 (alkaline), the temperature value was 28°C, the TDS value was 1548.3 mg/L, the TSS value was 291 mg/L, the DO value was 0.1 mg/L and dissolved iron (Fe2+) of 7.453 mg/L. After conducting research, it was found that the venture injector type micro bubble aeration process was able to increase the value of dissolved oxygen (DO) and reduce dissolved iron (Fe2+) in industrial waste water, the best increase in dissolved oxygen (DO) at 6 LPM air flow for 60 minutes was able to increase oxygen dissolved (DO) to 2.40 mg/L. The most efficient and effective reduction in the value of dissolved iron (Fe2+) at 6 LPM air flow with a time of 15 minutes was able to reduce the value of dissolved iron by 84.42%.
Keywords: industry waste; iron (Fe); air flow; micro bubble; aeration; waste water treatment
- Agustian, D., Windusari, Y., & Hasyim, H. (2023). Simple Water Treatment Methods to Reduce Fe (Iron) Levels in Well Water: Literature Study. Permas Scientific Journal, 13(3), 813-820.
- Arakawa, T., Yamamoto, T., & Shoji, S. (2008). Micro-bubble formation with organic membrane in a multiphase microfluidic system. Sensors and Actuators, A: Physical, 143(1), 58-63. https://doi.org/10.1016/j.sna.2007.06.038
- Arsawan, M., Suryasa, I. W. B., & Suarna, W. (1907). Utilization of Aeration Methods in Processing Oily Waste. Ectrophic Journal, 2(2), 1-9.
- Elmanfe, G. M., Tyeb, T. A., Abdelghani, K. A., Abdulathim, A. A., Asbeeh, J. A., Muftah, H. S., & Ali, A. F. (2022). Assessment of Groundwater Wells Pollution by Some Heavy Metals in El-Beida City-Libya. Journal of Pure & Applied Sciences, 15(July), 3-8.
- Fan, W., Li, Y., Lyu, T., Chen, Z., Jarvis, P., Huo, Y., Xiao, D., & Huo, M. (2023). A modelling approach to explore the optimum bubble size for micro-nanobubble aeration. Water Research, 228, 119360.
- Febrina, L., & Ayuna, A. (2014). S Study of Reducing Iron (Fe) and Manganese (Mn) Levels in Ground Water Using Ceramic Filters. Journal of Technology, 7(1), 36-44. https://jurnal.umj.ac.id/index.php/jurtek/article/download/369/341
- Fiksel, J., McDaniel, J., & Mendenhall, C. (1999). Measuring progress towards sustainability principles, process, and best practices. Ohio: Battelle Memorial Institute.
- Gautam, P. K., Gautam, R. K., Banerjee, S., Chattopadhyaya, M., & Pandey, J. (2016). Heavy metals in the environment: fate, transport, toxicity and remediation technologies. Nova Sci Publishers, 60, 101-130.
- Ghernaout, D. (2019). Aeration process for removing radon from drinking water—A review. Applied Engineering, 3(1), 32-45.
- H, D. D. N., Jati, A. W. N., & Zahida, F. (2009). Variations in Aeration Time in Liquid Waste Processing Plants in the Soy Sauce and Sauce Industry. 37(2), 2-5. http://ci.nii.ac.jp/naid/40016575325/
- Kurratul, U., Ilim, & Simanjuntak, W. (2012). Study of the Effect of Potential, Contact Time, and pH on the Method of Electrocoagulation of Restaurant Liquid Waste Using Fe Electrodes with Monopolar and Dipolar Arrangements. SNSMAP Proceedings, III(978), 445-450.
- Lei, H. (2010). Experimental and Modeling Studies of Bubble Degassing University of Calgary Calgary, AB, Canada].
- Nicola, F. (2015). Relationship between Conductivity, TDS (Total Dissolved Solid) and TSS (Total Suspended Solid) with Fe2+ and Total Fe Levels in Dug Well Water. Thesis, 27-27. http://repository.unej.ac.id/bitstream/handle/123456789/65672/Ainul Latifah-101810401034.pdf?sequence=1
- Oztemel, E., & Gursev, S. (2020). Literature review of Industry 4.0 and related technologies. Journal of intelligent manufacturing, 31, 127-182.
- Raimon. (2011). Integrated Laboratory Wastewater Treatment Using a Continuous System. Journal of Industrial Research Dynamics, 22(2), 18-27.
- Ramandani, A. A. (2022). Optimizing the Ratio of Sodium Bicarbonate (NaHCO3) and Benzoic Acid (C6H5COOH) to Increase the Durability of BW Tangerine Juice (Citrus Sp.Var.Chokum Bw). http://repository.polinela.ac.id/4036/
- Ramandani, A. A., Shintawati, S., Aji, S. P., & Sunarsi, S. (2022). Pemanfaatan Lignin Serai Wangi Sebagai Lignin Resorsinol Formaldehida (LRF) Menggunakan Ultrasonic Microwave-Assisted Extraction (UMAE). CHEESA: Chemical Engineering Research Articles, 5(1), 40-40. https://doi.org/10.25273/cheesa.v5i1.10348.40-48
- Rofik, D. A. (2020). Design and Analysis of Microbubble Generator (MBG) Tools for Venturi Nozzel Type Fish Pond Aeration. Gorontalo Journal of Infrastructure and Science Engineering, 3(2), 24-24. https://doi.org/10.32662/gojise.v3i2.1206
- Sadatomi, M., Kawahara, A., Kano, K., & Ohtomo, A. (2005). Performance of a new micro-bubble generator with a spherical body in a flowing water tube. Experimental Thermal and Fluid Science, 29(5), 615-623. https://doi.org/10.1016/j.expthermflusci.2004.08.006
- Suyasa, W. B. (2015). Water Pollution and Wastewater Treatment. Udayana University Press, 153-153.
- Temesgen, T., Bui, T. T., Han, M., Kim, T. i., & Park, H. (2017). Micro and nanobubble technologies as a new horizon for water-treatment techniques: A review. Advances in Colloid and Interface Science, 246(June), 40-51. https://doi.org/10.1016/j.cis.2017.06.011
- van de Griend, M. V., Warrener, F., van den Akker, M., Song, Y., Fuchs, E. C., Loiskandl, W., & Agostinho, L. L. F. (2022). Vortex Impeller-Based Aeration of Groundwater. Water (Switzerland), 14(5). https://doi.org/10.3390/w14050795
- Venkataramani, V. (2021). Iron Irons Homeostasis and Metabolism: Two Sides of a Coin. Ferroptosis: Mechanism and Diseases, 25-40.
- Wardiyati, S., Sulungbudi, G. T., & Ridwan. (2010). Adsorpsi Ion Pb2+ Dan Ni2+ oleh Nano Partikel γ-Fe2O3 /Fe3 O4. Indonesian Journal of Materials Science, 11(2), 83-87.
- Xu, P., Zeng, G. M., Huang, D. L., Feng, C. L., Hu, S., Zhao, M. H., Lai, C., Wei, Z., Huang, C., & Xie, G. X. (2012). Use of iron oxide nanomaterials in wastewater treatment: a review. Science of the Total Environment, 424, 1-10.
- Yang, T. W. (2020). Effect of Different Types of Static Mixer Geometry on Quality of Microbubble Generation University of Malaya (Malaysia)].
- Yazid, E. A., Wafi, A., & Saraswati, A. (2021). Techniques for Reducing Iron (Fe) Content in Groundwater: an Article Review. Journal of Islamic Pharmacy, 6(1), 40-45. https://doi.org/10.18860/jip.v6i1.12078
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