On modeling and optimization of micro-photosynthetic power cells

•Initial attempt at modeling μPSC.•Model validated using test data not used in parameter estimation.•Simulation analysis to understand performance improvement possibilities.•Explicit optimization formulations identify promising device designs. In this paper, we describe a model for a micro photosynt...

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Bibliographic Details
Published in:Computers & chemical engineering 2017-12, Vol.107, p.284-293
Main Authors: Tanneru, Hemanth Kumar, Suresh, Resmi, Rengaswamy, Raghunathan
Format: Article
Language:English
Subjects:
1-D model
Design optimization
Mathematical modeling
Micro photosynthetic power cell
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Summary:•Initial attempt at modeling μPSC.•Model validated using test data not used in parameter estimation.•Simulation analysis to understand performance improvement possibilities.•Explicit optimization formulations identify promising device designs. In this paper, we describe a model for a micro photosynthetic power cell (μPSC). μPSC is an electrochemical device which harnesses electrons and protons from the electron transport chains of photosynthesis (in the presence of light), and respiration (in the absence of light) occurring inside an oxygenic photosynthetic organism to generate electricity. μPSC has been identified as a potential power generating device for low power applications. A one dimensional model for a μPSC based on mass balances of species in the anode and cathode chambers considering unsteady one dimensional diffusion is developed. The governing equations are solved to obtain the v−i characteristics of a μPSC device. The unknown parameters in the model are estimated from experimental data. The model with its estimated parameters is validated using test v−i characteristic data. Simulation analysis is performed to understand performance improvement possibilities. Explicit optimization formulations to identify promising device designs are also explored.
ISSN:0098-1354
1873-4375
DOI:10.1016/j.compchemeng.2017.02.015