A swirling flow-film cooling structure with offset impingement holes is proposed to achieve higher cooling efficiency of turbine blade leading edge. In this research, experimental investigations and numerical simulations were carried out on two structures distinguished by whether impingement jets are tangential-wisely offset from the centerline with Reynolds number ranging from 20000 to 50000. The internal heat transfer, flow resistance, and flow field characteristics were obtained. Transient liquid crystal thermal imaging technique was used in experiments to measure detailed Nusselt number distributions on the inner surface of leading edge, and the flow field was analyzed with the results of numerical simulation to explain the mechanism of heat transfer enhancement. Experimental results show that internal swirling flow of blade leading edge can improve the overall average Nusselt number by 4.0%~9.4% and reduce the pressure loss by 5.6%~6.4%. Numerical results suggest that tangential jets create intense swirling flow because of the concave surface of blade leading edge, which significantly enlarges the high heat transfer region and improves the uniformity of internal heat transfer.