T The increasing demand for clean water in industrial areas requires a reliable and sustainable water supply system. the operational success of an industrial estate is highly dependent on the availability of basic infrastructure, one of which is the water treatment plant (wtp) as the main source of clean water supply. along with the growth in the number of tenants and operational load, the wtp operates close to its design capacity, creating potential risks to future water supply adequacy. in addition to capacity constraints, the existing wtp operation indicates relatively high energy consumption, fluctuations in chemical dosing, and a predominantly reactive maintenance pattern, which collectively contribute to increasing operational and maintenance (o&m) costs.the objective of this research is to determine the optimal strategy for fulfilling clean water supply requirements through the optimization of operational and maintenance costs of the water utility network at an industrial area wtp. the strategies evaluated include an operational and maintenance (o&m) strategy, a small capital expenditure (capex) strategy through the implementation of a streaming current monitor (scm) and supporting instrumentation, and a large capex strategy in the form of wtp construction or capacity expansion to improve supply reliability.the research method applies financial analysis based on present value (pv) and life cycle cost (lcc) with an analysis period of 20 years and a discount rate of 8%. the data used consist of historical wtp operational data, including electricity consumption, chemical usage, raw water cost, and maintenance cost, as well as estimated investment data for each alternative strategy. to strengthen the decision-making process, the analysis is supported by scenario analysis and sensitivity analysis on key parameters such as discount rate, initial investment cost, and operational cost saving rates.the results indicate that the operational and maintenance (o&m) strategy is the most optimal and highest-priority option, as it provides the greatest cumulative cost savings without requiring initial investment. the total pv saving of opex and mex ranges from idr 230.07 to 677.51 million, with idr 495.26 million under the moderate scenario. the small capex strategy generates a positive npv saving of idr 51.48 million; however, its feasibility is sensitive to the magnitude of initial investment and the level of chemical cost savings. meanwhile, the large capex strategy results in a total life cycle cost of idr 57,415.00 million and is therefore more appropriately positioned as a medium- to long-term strategy for capacity fulfilment and improvement of clean water supply reliability. accordingly, this research recommends a phased implementation approach to ensure sustainable water services and operational cost efficiency in industrial areas.