4.5 Article

Methanol steam reforming reactor design for efficient photovoltaic-thermochemical power generation

Journal

SUSTAINABLE ENERGY & FUELS
Volume 7, Issue 13, Pages 2997-3013

Publisher

ROYAL SOC CHEMISTRY
DOI: 10.1039/d2se01746f

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The photovoltaic-thermochemical (PVTC) hybrid system improves solar power efficiency and dispatchability through the complementation of concentrated solar PV and solar thermochemical conversions. However, the high concentration ratio in the PVTC system presents challenges to temperature uniformity and energy conversion performance. By analyzing the heat transfer and reaction performance of four different compact reactors for methanol steam reforming, it was found that the reactor structure has a significant influence on these factors. The optimal net solar-electric efficiency of the PVTC system with the six-chamber reactor is 42.2%, higher than the previous study at the same operating temperature.
The photovoltaic-thermochemical (PVTC) hybrid system is an emerging technology for improving the efficiencies and dispatchability of solar power via complementation between concentrated solar PV and solar thermochemical conversions. In order to improve the PV efficiency and decrease the heat losses of the reactor, the concentration ratio is usually as high as 500-1000 in the PVTC hybrid system. However, the high concentration ratio presents a serious challenge to reactor temperature uniformity and energy conversion performance. In order to improve the heat transfer performance of the reactor and the solar-electric efficiency of the PVTC hybrid system, four compact reactors for methanol steam reforming were designed and manufactured with different internal structures. Through analysis on heat transfer, flow field and reaction via numerical simulation and experimental test of the four reactors, it is found that the reactor structure has a great influence on the heat transfer and the reaction performances. At 250 degrees C and 1.50 ml min(-1) methanol solution flow rate, the methanol conversion of the six-chamber reactor is 87.3%, 23.0 percentage points higher than that of the cavity reactor. The optimal net solar-electric efficiency of the PVTC system with the six-chamber reactor can reach 42.2% at 250 degrees C and 1.75 ml min(-1) methanol solution flow rate, which is 3.5 percentage points higher than that of the previous study at the same operating temperature.

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