In recent years, the impact of climate change has led to an increase in extreme rainfall events, significantly raising the load on urban drainage systems and the risk of flooding. Consequently, effectively managing urban sewer systems, reducing flood risks, and enhancing disaster response capabilities have become urgent issues. This study selects the Zhongshan Pumping Station catchment area in Taipei City as the research area, collecting data on rainfall, sewer water levels, internal and external water levels of the pumping station, and historical operation records of the Zhongshan Pumping Station. Multiple water level prediction models with a 10-minute interval are established by adjusting model parameters using Random Search. Combined with an optimized operation strategy, these models are integrated into a pumping unit operation strategy model. This study is divided into two main parts: water level prediction and operation strategy. For water level prediction, Convolutional Neural Networks combined with Back Propagation Neural Networks (CNN-BP) and Long Short-Term Memory Neural Networks (LSTM) are established to predict sewer water level for the next 10 to 40 minutes (T+1 to T+4). Results from both models show that CNN-BP is the superior model. Therefore, the CNN-BP model is used to predict the internal water level for the next hour (T+1 to T+6) and the external water level for the next hour (T+1 to T+6). For operation strategies, the Non-dominated Sorting Genetic Algorithm Ⅲ (NSGA-Ⅲ) is constructed to optimize the pumping station operation rules. The best operation rules are selected using Entropy-TOPSIS, and the optimized operation is simulated. Finally, the water level prediction and NSGA-Ⅲ optimized operation rules simulation process are integrated as training samples for the Adaptive Network-Based Fuzzy Inference System (ANFIS) to establish a pumping unit operation strategy model, predicting the number of pump operations. Results indicate that the CNN-BP model's prediction of sewer water level across all monitoring stations outperforms the LSTM model. Correlation analysis can reduce the input items of the CNN-BP model for predicting internal water levels. T+1 to T+3 can generally grasp the water level trends well enough to serve as a reference for pumping station operations in predicting high water level events. Due to the small amplitude of water level changes in predicting external water levels, the CNN-BP model can accurately capture external water level variability. Through NSGA-Ⅲ, three objective functions are optimized: minimizing risk value (Obj1), minimizing the total difference in front and back water level (Obj2), and minimizing the number of pump switches (Obj3). The optimized operation simulation results show that all three objective functions perform better than the existing pumping station rules simulation, with improvement rates of 3.07%, 47.15%, and 55.14%, respectively. The optimized operation simulation results significantly enhance the pumping station's performance in terms of risk reduction, water level stability, and pump operation frequency. Finally, the ANFIS model predicts the number of optimized pump operations based on real conditions, with input items selected through correlation analysis. The prediction results show that the ANFIS model can generally grasp the trend of pumping unit operations. This study combines water level prediction models and optimized pumping station operations to establish a pumping unit operation strategy model through ANFIS. This real-time and adaptive model enables quick monitoring of rainfall and overall flood drainage system water level during typhoons or heavy rain. It provides effective pump operation references to the pumping station management unit, enhancing disaster warning and response capabilities, and realizing smart flood management.