In this research, a dual-channel sound-insulation structure with subwavelength size and dimension is proposed. It can achieve a broadband sound insulation and matain air circulation due to ventilated an air channel. The structure is farther miniaturized for developing an in-ear low-frequency reducer. Noise-insulation earplugs can achieve broadband noise reduction and reduce the sultry feeling caused by traditional earplugs. In this research, an acoustic transmission line model with acoustic radiation impedance, radiation effect, and thermal viscosity loss is established by analyzing the transmission of sound waves in the duct. Compared with finite element method (FEM), this method can design multiple air-channel structures and optimize their geometry more effectively, and the model can also calculate the sound absorption rate with transmission loss and the sound absorption rate of resonant acoustic panels without transmission loss. The simulation results of both models match well and are in good agreement with the experimental results. The noise cancellation performance of the in-ear low-frequency noise-cancelling earplugs is verified by the closed sound field experiment and the finite element simulations. Finally, the dual-flow channel structure and miniaturized in-ear low-frequency noise-cancelling earplugs have the performance of low-frequency anti-noise ventilation, reaching 66% and 100% of the 10 dB proportional bandwidth, and 68% of the air flow rate, and its structural thickness reaches 0107 and 0.11 . The flow-through subwavelength structure has potential applications in large ventilated soundproof walls or in-ear noise-cancelling earplugs in the future.