To maintain the quality of the water environment, the Ministry of Environment has designated the total quantity control of wastewater discharge as a key strategy for future water quality management. In the Nankan River Basin, located in Taoyuan City, the thriving printed circuit board manufacturing industry has led to excessive discharge of heavy metal copper in wastewater, surpassing the river’s assimilative capacity. In response, the Taoyuan City Environmental Protection Bureau issued a total quantity control policy for heavy metal copper discharge in the Nankan River Basin in 2017. This policy aims to regulate the total copper discharge within the basin and safeguard the water quality of irrigation channels in northern Taoyuan. This study utilizes the WASP water quality model to analyze the river’s assimilative capacity and assess the effectiveness of the current total quantity control policy in the Nankan River. Additionally, several commonly used international pollutant allocation methods are applied for simulation calculations to provide recommendations for future policy implementation. For the simulation, this study adopts a design flow (Q80) based on the flow corresponding to the 80% exceedance probability in the daily flow duration curve, combined with the average tributary drainage flow. The total allowable heavy metal copper load is calculated by summing the assimilative capacities of upstream monitoring stations while incorporating a 5% margin of safety. The resulting permissible discharge limits are as follows: •Upstream of Dapu Bridge: 1.76 kg/day •Upstream of Guishan Bridge: 3.39 kg/day •Upstream of Dakuixi Bridge: 9.20 kg/day •Upstream of Nankanxi Bridge: 16.28 kg/day •Upstream of Kanxia Bridge: 26.97 kg/day •Upstream of Zhuwei Bridge: 30.71 kg/day Using the approved discharge volume and the effluent standard (1.5 mg/L) for current pollution load estimation, it was found that, except for the Guishan Bridge section, the permitted pollution discharge in all other river sections significantly exceeds the river’s allowable discharge capacity. This study explores various pollutant allocation methods, including equal discharge concentration, equal discharge volume, current discharge concentration with an equal reduction rate, regional equal discharge concentration, hierarchical control based on current discharge concentration and reduction rates, targeted industry reduction, and hierarchical control for targeted industries. Among these, targeted industry reduction and hierarchical control for targeted industries appear to be the most feasible approaches. However, achieving absolute fairness in total quantity control through any allocation method remains challenging. Therefore, this study recommends that after the initial allocation plan is developed, intensive communication and coordination with stakeholders within the river basin should be conducted. Additionally, the implementation of pollutant trading and offset mechanisms can be considered to leverage market forces in supporting policy execution.