Past studies showed that both frequency and intensity of extreme rainfall increase when atmospheric temperature increases. From basic thermodynamic principle, the saturated atmospheric moisture content increases about 7% per °C. If there is no significant change in the dynamical forcing for extreme rainfall events, the extreme precipitation might increase with temperature in a similar fashion. However, there are studies indicating that, using the local observed data from surface stations, the extreme rainfall intensity can increase twice as large as compared to the thermodynamic theory. Further, the extreme rainfall actually decreases as the background surface air temperature or dew point temperature increases when the surface air temperature exceeds 25°C or the dew point temperature reaches 26 °C. Our study tries to use the rainfall type and event duration to explain the negative relationship between temperature increase and extreme rainfall intensity decrease. After classifying the summer rainfall types, we found that the negative temperature–rainfall intensity relationship is mainly due to diurnal convection and other unclassified convective rainfall types. The daily mean temperatures are higher in those two rainfall types due to the relatively high morning temperature before the start of a heavy rainfall event while their intensities are not as strong as compared to the extreme rainfall associated with typhoons or mesoscale convective systems during the Mei-Yu front. In addition, the extreme rainfall at higher temperature is typically with a shorter duration and weaker intensity. Both contribute to the negative relationship between temperature and extreme rainfall intensity. For the negative dew-point temperature and extreme rainfall intensity relationship, the weaker extreme rainfall at higher dew-point temperature is mainly due to rainfall associated with typhoons and other unclassified convective rainfall types. With additional rainfall event duration information, we found that both the rainfall intensity and duration increases with the dew point temperature for diurnal convective rainfall. Since diurnal convective rainfall is typically a local scale system triggered by instability, both higher temperature and more moisture, therefore higher dew-point temperature favor larger extreme afternoon rainfall. The lower background dew point temperatures associated with more extreme rainfall for typhoon events is typically due to the fact that the stronger typhoon rainfall has a longer rainfall duration. The background temperatures drop substantially for those long-lasting extreme rainfall events.