A comprehensive experimental approach was employed, utilizing a range of treatment techniques including ion exchange resin, activated carbon filtration, activated carbon and zeolite combined, and chemical precipitation with AgNO3 and FeCl3. Analysis of crucial parameters such as pH, turbidity, total organic carbon, zeta potential, and conductivity were conducted on both treated and control tap water samples. The research demonstrates that IER is highly effective in reducing turbidity, electrical conductivity, and removing ions, making it a superior contender for industrial water reuse. Activated carbon, though promising for reducing turbidity, offers less comprehensive water quality improvement. Combining activated carbon and zeolite shows potential but necessitates a tailored approach based on the primary water purification goal. Chemical precipitation with AgNO3 and FeCl3 exhibits significant promise for chloride ion removal and coagulation. However, optimizing dosage and potentially incorporating filtration techniques like activated carbon is crucial for maximizing treatment effectiveness while preventing over-precipitation. Careful management of anion levels is essential, requiring adjustment of treatment protocols to ensure suitability for specific industrial uses.