Kuroshio off northeast Taiwan has been studied using a numerical ocean model and available observations. Particularly, the seasonal variability of upwelling near the southern East China Sea shelf and the interaction between typhoon Nari and Kuroshio have been extensively investigated. Based on model simulation, the vertical velocity in the upwelling region is positive in all months, indicating the upwelling is a year-round phenomenon. Furthermore, opposite seasonal tendencies of upwelling are found for different depth range. The vertical velocity integrated from surface to 100 m is weaker in winter than in summer, whereas it reaches its minimum during summertime in the top 30 m. Different mechanisms are responsible for this seasonal discrepancy. Seasonality in the upper 100 m is influenced by the Kuroshio migration. In winter, Kuroshio intrudes onto the shelf and prevents the upwelling developing, and therefore vertical velocity is weaker. As Kuroshio retreats from the shelf in summer, vertical velocity becomes stronger. On the other hand, seasonal tendency in the top 30 m is attributed to the local wind speed that is generally weaker in summer but becomes much stronger during winter. We also use the model results and satellite data to discuss the interaction between Typhoon Nari and Kuroshio. Nari ambled around and crossed Kuroshio several times, which causes variations in typhoon intensity. Model simulation suggests that a cyclonic eddy triggered by Nari has occurred in regions north of Kuroshio, as a result, the cold SST patch is only visible to the north of the Kuroshio axis. The cyclonic circulation penetrates much deeper for a slowly-moving storm, regardless of the typhoon intensity. Near-inertial frequency oscillations after typhoon departure are simulated by the model in terms of the vertical displacement of isotherms. The SST cooling caused by upwelling and vertical mixing is effective in cooling the upper ocean several days after the storm has passed. At certain locations, surface chlorophyll a concentrations increase significantly after Nari’s departure. Upwelling and mixing bring nutrient-rich subsurface water to the sea surface, causing enhancement of phytoplankton bloom.