Modeling and optimization of solar thermal-photovoltaic vacuum membrane distillation system by response surface methodology
Document Type
Article
Publication Date
1-1-2020
Abstract
Response surface methodology is used in this study to model and optimize a solar thermal-photovoltaic vacuum membrane distillation (STPVMD) system with PVDF hollow fiber membrane. Regression models have been developed to forecast the effect of various operation factors on the permeate flux and the energy consumption. The operation factors in the model include the feed inlet temperature, the feed flow rate and the vacuum pressure. Analysis of variance is used to statistically validate the regression models. With permeate flux as the objective function of optimization, the optimal operation parameters are found to be 63 °C for the feed inlet temperature, 237 L/h for the feed flow rate, and 750 kPa for the vacuum pressure. Experimental tests show that the resulting permeate flux is 6.26 L/m2·h, which is slightly higher than the predicted value of 6.05 L/m2·h. The corresponding energy consumption is predicted to be 12.52L/kW·h, demonstrating the effectiveness and reliability of the models.
Identifier
85075525631 (Scopus)
Publication Title
Solar Energy
External Full Text Location
https://doi.org/10.1016/j.solener.2019.11.006
ISSN
0038092X
First Page
230
Last Page
238
Volume
195
Fund Ref
National Natural Science Foundation of China
Recommended Citation
Deng, Hongling; Yang, Xiaohong; Tian, Rui; Hu, Junhu; Zhang, Bo; Cui, Fangda; and Guo, Guangyu, "Modeling and optimization of solar thermal-photovoltaic vacuum membrane distillation system by response surface methodology" (2020). Faculty Publications. 5703.
https://digitalcommons.njit.edu/fac_pubs/5703
