本文对含有Botryococcus Braunii UTEX 572的微生物碳捕获电池阴极室内的光合有效辐射(Photosyntheticallyactive radiation,PAR)分布建立数学模型。采用离散坐标法(Discrete Ordinate Method,DOM)求解一维稳态辐射传递方程(Radiative transfer equation.RTE),使用SMARTS(the Simple Model for Atmospheric Transmission of Sunshine)模式对边界条件进行计算。在所建模型基础上,对400~800 nm波长范围的阴极室内PAR分布情况进行计算,并结合Botry-ococcusBraunii UTEX 572的生长动力学对CO_2的局部吸收速率进行研究。同时对不同散射处理方法,气泡含量以及藻类浓度对CO_2捕获速率的影响进行对比,为改善光在微生物碳捕获燃料电池阴极室的分布和阴极室优化设计提供依据。
The entransy theory, which can be used to optimize the heat transfer network of a solar power tower system (SPTS) and im- prove its energy efficiency, was introduced in this paper. Firstly, the irreversibility of the heat transfer processes in a SPTS was analyzed and the total entransy dissipation equation of a SPTS was derived. Then, two types of optimization problems (reduc- ing the total circulating flow rate or the total heat-exchanging area) of a SPTS were solved with conditional extremum model based on the formulas of total entransy dissipation. Finally, the entransy dissipation-based optimization principle was applied to a simple SPTS without re-heater and a complex SPTS with a re-heater. The results showed that under the chosen calculation conditions the minimum total thermal conductance was 19306.03 W K-~ for a SPTS without re-heater when the total heat ca- pacity rate of heat transfer fluid (HTF) was 3200 W K-1. The minimum total thermal conductance was about 7.9% lower than the value predicted based on the typical outlet temperature of a receiver. This meant that the total heat exchange area or initial investment could be effectively reduced under the prescribed total HTF circulating flow rate. We also studied the variation trends of the two optimized results including minimum total HTF heat capacity rate and minimum total thermal conductance. The minimum total HTF heat capacity rate decreased with the given total thermal conductance, the minimum total thermal conductance decreased first and then increased with the given total HTF heat capacity rate. We also found that for a SPTS with a re-heater, the mixing temperature and the mixing position of HTF had significant effects on the two types of optimization problems.
