Experimental Calibration of a Biohydrogen Production Estimation Model

IF 0.5 Q4 ENGINEERING, MECHANICAL
F. Dias, J. Vargas, Sam Yang, V. Kava, W. Balmant, A. Mariano, J. Ordonez
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引用次数: 1

Abstract

A dynamic physics-based model developed for the prediction of biohydrogen production in a compact tubular photobioreactor (PBR) was calibrated experimentally. The spatial domain in the model was discretized with lumped control volumes and the principles of classical thermodynamics, mass, species, and heat transfer were combined to derive a system of ordinary differential equations, whose solution was the temperature and mass fraction distributions across the entire system. Two microalgae species, namely, Acutodesmus obliquus and Chlamydomonas reinhardtii strain cc125, were cultured in triplicate with different culture media via indirect biophotolysis. Measured biomass and hydrogen concentrations were then used to adjust the specific microalgae growth and hydrogen production rates in the model based on residual sum of squares (RSS) and the direct search method. Despite its simplicity, the presented volume element model was verified to well predict both hydrogen and biomass concentration over time. The microalgae growth rate for each species was determined as 2.16 μalga,0 s−1 and 0.91 μalga,0 s−1 for A. obliquus and C. reinhardtii strain cc125, respectively, where μalga,0 is the specific growth rate of Scenedesmus almeriensis for given temperature and irradiance. The adjusted maximum hydrogen production rates for the local nonmutant A. obliquus and for C. reinhardtii strain cc125 were 1.3 × 10−7 s−1 and 4.1 × 10−7 s−1. Consequently, these hydrogen production rates were 59 times and 19 times smaller, respectively, than that for the mutant C. reinhardtii strain cc849.
生物制氢估算模型的实验标定
建立了一种基于动态物理的小型管状光生物反应器(PBR)产氢预测模型,并对其进行了实验标定。利用集总控制体积对模型的空间域进行离散化,结合经典热力学、质量、物质和传热原理,推导出一个常微分方程组,其解为整个系统的温度和质量分数分布。采用间接生物光解的方法,在不同培养基上三次培养斜尖针叶藻(Acutodesmus obliquus)和莱茵衣藻(Chlamydomonas reinhardtii)菌株cc125。然后利用测量的生物量和氢气浓度,基于残差平方和(RSS)和直接搜索法调整模型中特定微藻的生长和产氢率。尽管它很简单,但所提出的体积元模型被证明可以很好地预测氢和生物质浓度随时间的变化。各菌种的微藻生长速率分别为2.16 μalga,0 s−1和0.91 μalga,其中A. obliquus和C. reinhardtii菌株cc125的生长速率分别为0 s−1,其中μalga,0为给定温度和辐照度下almeriensis的比生长速率。调整后的最大产氢率对本地非突变型斜弧菌和莱茵哈蒂C.菌株cc125分别为1.3 × 10−7 s−1和4.1 × 10−7 s−1。因此,这些产氢率分别比突变菌株cc849低59倍和19倍。
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来源期刊
CiteScore
1.60
自引率
16.70%
发文量
12
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