Structural design and performance research of methanol steam reforming microchannel for hydrogen production based on mixing effect

Abstract

To improve hydrogen production performance of reforming, a plate-type microchannel carrier plate with a ridge structure was designed based on the mixing effect. The mixing effect of the ridge structure on the hydrogen production performance of reforming was analyzed. Then the effects of geometric parameters (shape, size, spacing, and tilt angle) of the ridge structure on heat, mass transfer, and the hydrogen production performance of the reforming process were modelled and simulated. Finally, data analysis and structural optimisation of microchannels with the ridge structure were conducted via methanol steam reforming hydrogen production experiments. The experimental results show that the trapezoidal ridge structure microchannel (T-type0) achieved the best hydrogen production performance, whose methanol conversion rate was 60.8%, under the gas hourly space velocity of 48,757 mL/(g&h). Especially compared with the ordinary rectangular microchannel structure (O-type0), the methanol conversion rate of the trapezoidal ridge structure microchannel increased by 25.2%. Moreover, the pressure drop of this microchannel did not increase significantly, indicating that the structure did not significantly increase the pressure drop loss while enhancing the heat and mass transfer. Therefore, the ridge structure proposed in this paper can effectively improve heat and mass transfer performance and the hydrogen production efficiency of the microchannel.