High-resolution meteorological data are essential for precise decision-making in agriculture, improving crop yield prediction, and enhancing resilience to weather-related disasters. Among meteorological variables, solar radiation is a key factor determining photovoltaic power generation efficiency and crop growth conditions, thus requiring HR data for accurate prediction. This study proposes an efficient SR model based on the SwinIR framework, in which multiple Residual Swin Transformer Blocks are reduced and integrated with a Hybrid Block of CNN and Transformer and a Detail Branch. The proposed model maintains strong global context learning ability while reducing computational cost and accurately restoring local variations in radiative patterns. Experimental results using CM SAF’s SARAH-3 surface solar radiation data show improvements over SwinIR by 0.0435 dB in PSNR, 0.0002 in SSIM, and reductions of 0.0195 W/m² in RMSE and 0.0369 W/m² in MAE. Moreover, the model achieved finer restoration along cloud boundaries and rapid irradiance transitions, while reducing computation by approximately 34%, demonstrating its efficiency and effectiveness for high-fidelity solar radiation reconstruction.