Separation technology for resource recovery

Separation technology for resource recovery

With the rise in the number of urban cities around the world, there is also a corresponding increase in the demand for both resources and water. The increased demand and consumption of such resources would lead to a corresponding increase in waste generated. Wastewater, in particular, needs to be p...

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Main Author: Lee, Yun Ying
Other Authors: She Qianhong
Format: Final Year Project
Language:English
Published: Nanyang Technological University 2021
Subjects:
Engineering::Environmental engineering
Online Access:https://hdl.handle.net/10356/149585
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1495852021-05-23T14:05:03Z Separation technology for resource recovery Lee, Yun Ying She Qianhong School of Civil and Environmental Engineering Singapore Membrane Technology Centre QHSHE@ntu.edu.sg Engineering::Environmental engineering With the rise in the number of urban cities around the world, there is also a corresponding increase in the demand for both resources and water. The increased demand and consumption of such resources would lead to a corresponding increase in waste generated. Wastewater, in particular, needs to be properly treated to prevent the negative impacts that it may bring such as water pollution or eutrophication. Domestic wastewater is known to have high quantities of Nitrogen, which also serves as a key resource in aiding the growth of crops in the agricultural industry. This project explores the possibility of the recovery of N − NH4 in wastewater through the use of electrodialysis to become a phosphate mineral known as Struvite. The formation of Struvite using N − NH4 in wastewater was explored synthetically in 3 stages: (1) increasing the concentration of N − NH4+ in wastewater; (2) increasing the pH of concentrated solution till pH 9.5; and (3) external addition of PO43−as KH2PO4 and Mg2+ as brine. Results have shown that the formation of Struvite was successful, but it was only successful under high concentrations of N − NH4+and would require a concentration factor of about 10 times. Stage 1 (increasing the concentration of N − NH4+in wastewater) proved to be the most crucial step in the formation of Struvite. If concentrations of N − NH4+ were not high enough, Struvite formation would not be significant. There was seen to be a 3-fold increase in the concentration of N − NH4+ during the electrodialysis process of stage 1, done with a concentration factor of 15 times. The energy consumption for such stage 1 was calculated to be about 14.69kWh/Kg N − NH4. Bachelor of Engineering (Environmental Engineering) 2021-05-23T14:05:03Z 2021-05-23T14:05:03Z 2021 Final Year Project (FYP) Lee, Y. Y. (2021). Separation technology for resource recovery. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/149585 https://hdl.handle.net/10356/149585 en application/pdf Nanyang Technological University
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Engineering::Environmental engineering
spellingShingle Engineering::Environmental engineering
Lee, Yun Ying
Separation technology for resource recovery
description With the rise in the number of urban cities around the world, there is also a corresponding increase in the demand for both resources and water. The increased demand and consumption of such resources would lead to a corresponding increase in waste generated. Wastewater, in particular, needs to be properly treated to prevent the negative impacts that it may bring such as water pollution or eutrophication. Domestic wastewater is known to have high quantities of Nitrogen, which also serves as a key resource in aiding the growth of crops in the agricultural industry. This project explores the possibility of the recovery of N − NH4 in wastewater through the use of electrodialysis to become a phosphate mineral known as Struvite. The formation of Struvite using N − NH4 in wastewater was explored synthetically in 3 stages: (1) increasing the concentration of N − NH4+ in wastewater; (2) increasing the pH of concentrated solution till pH 9.5; and (3) external addition of PO43−as KH2PO4 and Mg2+ as brine. Results have shown that the formation of Struvite was successful, but it was only successful under high concentrations of N − NH4+and would require a concentration factor of about 10 times. Stage 1 (increasing the concentration of N − NH4+in wastewater) proved to be the most crucial step in the formation of Struvite. If concentrations of N − NH4+ were not high enough, Struvite formation would not be significant. There was seen to be a 3-fold increase in the concentration of N − NH4+ during the electrodialysis process of stage 1, done with a concentration factor of 15 times. The energy consumption for such stage 1 was calculated to be about 14.69kWh/Kg N − NH4.
author2 She Qianhong
author_facet She Qianhong
Lee, Yun Ying
format Final Year Project
author Lee, Yun Ying
author_sort Lee, Yun Ying
title Separation technology for resource recovery
title_short Separation technology for resource recovery
title_full Separation technology for resource recovery
title_fullStr Separation technology for resource recovery
title_full_unstemmed Separation technology for resource recovery
title_sort separation technology for resource recovery
publisher Nanyang Technological University
publishDate 2021
url https://hdl.handle.net/10356/149585
_version_ 1701270462824185856

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