The aim of this study is to investigate the variations of flow and thermal fields in the cooling channel within the reciprocating channel, and the heat transfer rate on the heated crown of the channel is discussed. A Galerkin finite element formulation with ALE method is adopted to investigate the variations of the flow and thermal fields induced by the reciprocating motions of the channel with porous media. The heat transfer rates on different models that base on working fluid is air and data runs are performed for Reynolds numbers, frequencies, amplitudes, temperature differences and channel with porous media relative angles from horizon will be shown and discussed. Heat transfer rates are affected by cooling fluid flowing and reciprocating motion mutually. The enhancement of heat transfer rate is definite and the most achievement is about 20% in this work. Comparisons of both experimental and numerical results have good agreements and the channel with porous media can help the enhancement of heat transfer rate more. The porous media under the larger porosity situation could obtain more heat dissipation than the traditional solid one. The porous media with a very small mean porosity could result in reduction thermal performance.