Publication: Product and cost perspectives of phosphorus recovery from human urine using solid waste ash and sea salt addition – A case of Thailand
Issued Date
2020-04-15
Resource Type
ISSN
18791026
00489697
00489697
Other identifier(s)
2-s2.0-85077752260
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Mahidol University
Rights Holder(s)
SCOPUS
Bibliographic Citation
Science of the Total Environment. Vol.713, (2020)
Suggested Citation
Yada Pinatha, Chongchin Polprasert, Andrew J. Englande Product and cost perspectives of phosphorus recovery from human urine using solid waste ash and sea salt addition – A case of Thailand. Science of the Total Environment. Vol.713, (2020). doi:10.1016/j.scitotenv.2020.136514 Retrieved from: https://repository.li.mahidol.ac.th/handle/123456789/49605
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Title
Product and cost perspectives of phosphorus recovery from human urine using solid waste ash and sea salt addition – A case of Thailand
Abstract
© 2018 Elsevier B.V. Phosphorus (P) recovery from human urine was evaluated using the addition of MgCl2, sea salt and solid-waste (SW) incinerated ashes. The study objectives were to assess and compare their efficiency for P recovery, costs of chemicals added and relevant crystal characteristics. Results from the experiments conducted between pH range of 7–11 revealed that P precipitation efficiency was increased to 89–97% and 72–88% when MgCl2 and sea salt were added, respectively. Precipitates obtained from both cases were found to contain 10.8–17.1% P dry weight which is superior to commercial fertilizer (8.80% P). Based on SEM-EDS examination and chemical equilibrium thermodynamics, about 83% and 68% of precipitates were in the form of struvite for the addition of MgCl2 and sea salt, respectively. Although 18% less struvite was formed with sea salt added, cost was found to be reduced from 4.07 USD·(kg P)−1 for MgCl2 addition to 2.91 USD·(kg P)−1 using sea salt addition, representing a 28% cost reduction. Furthermore, SW ashes added into the urine increased P recovery efficiency about 6–17%. Addition also lowered the costs to 1.75 and 1.68 USD·(kg P)−1 for SW fly ash and bottom ash, respectively. Thus, ash addition reduced cost and provided an alternative to landfill disposal. However, addition of SW bottom ash might result in recovered P solids with lead concentration exceeding the EC limit for inorganic fertilizer. In summary, results of this study have demonstrated a pragmatic way to recover P from human urine with the use of sea salt and ash as alternative Mg source and seed. Results indicate that this practice not only produces a good-quality fertilizer as struvite for sustainable P management, but also helps protect the water environment, and support circular economy of P in human ecosystem.