The weaving industry generates wastewater containing high levels of suspended solids, dissolved solids, and synthetic dyes that can threaten aquatic ecosystems if discharged untreated. This study investigates the effectiveness of seaweed and coconut husk powder as combined adsorbents for improving weaving wastewater quality in Nusa Penida, Bali. Three treatment variations (V1, V2, and V3) were applied, while untreated wastewater served as the control. Key parameters measured included Total Suspended Solids (TSS), Total Dissolved Solids (TDS), and color, using standard water quality assessment methods. Results showed that treatment V3 provided the highest pollutant removal efficiency. TSS decreased significantly from 72.89 mg/L in the control to 14.78 mg/L after V3 treatment, while color values reduced drastically from 2202.6 TCU to 235.61 TCU. TDS also exhibited notable reductions, confirming the strong adsorption capacity of the combined materials. The superior performance of V3 suggests that the optimal ratio of seaweed and coconut husk powder enhances binding capacity and surface interaction with pollutants. Compared to conventional treatments, this method is cost-effective, environmentally friendly, and utilizes locally abundant resources, making it highly suitable for small-scale industries. Overall, the study demonstrates the potential application of natural adsorbents as a sustainable solution for weaving wastewater management, while further research is recommended to optimize large-scale application and evaluate reusability of the adsorbents

weaving wastewater treatment, TDS, TSS, color, adsorbent, seaweed, coconut fiber

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