The recent increase in computing power enables us to perform a global kilometer-scale (K-scale) “convection-resolving” model (GCRM) simulation on the climate time scale. While this approach is expected to reduce some uncertainties related to unresolved cloud processes in the climate system, we also found systematic model biases in both climatological statistics and variabilities, irrespective of grid spacing at least for O(1-10)-km scale. Considering that this situation partly comes from the poor constraint of a moisture-convection relation depending on model physics at a K-scale, we have revised the treatment of cloud microphysics and unresolved turbulent diffusion in the Nonhydrostatic ICosahedral Atmospheric Model (NICAM) for improved climate simulations on the K-scale. After this revision, we are now performing a 10-year AGCM-type simulation at 3.5-km horizontal mesh from January 2011 on the supercomputer “Fugaku”, and we have accomplished about 5-year integration. A preliminary analysis reveals that both the model revisions and 3.5-km horizontal resolution can seamlessly improve the reproducibility of atmospheric fields over a wide range of spatio-temporal scales: the climatological mean precipitation and OLR distributions, mid-latitude circulations, the Asian summer monsoon, spontaneous MJO realization, tropical cyclone intensity, and precipitation diurnal cycle. However, we also face challenges associated with the poor representation of low clouds in higher resolution simulations, which should be resolved in the ocean-coupled climate run in terms of the energy balance. This work can be a clue for understanding the merits and issues of K-scale GCRM climate simulations and providing a possible strategy for the future model development.