Optimization of operational conditions for continuous membrane distillation crystallization process with zero discharge
Membrane Distillation Crystallization (MDC) is an innovative approach which involves the integration of the Membrane Distillation (MD) process together with a crystallizer unit. By tapping onto the potentials of MD, it becomes possible to operate under a supersaturated state of the solution, thereby...
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sg-ntu-dr.10356-528712023-03-03T16:57:03Z Optimization of operational conditions for continuous membrane distillation crystallization process with zero discharge Lim, Deric Weikang. Wang Rong School of Civil and Environmental Engineering Singapore Membrane Technology Centre DRNTU::Engineering::Environmental engineering::Water treatment Membrane Distillation Crystallization (MDC) is an innovative approach which involves the integration of the Membrane Distillation (MD) process together with a crystallizer unit. By tapping onto the potentials of MD, it becomes possible to operate under a supersaturated state of the solution, thereby achieving the objective of zero discharge to the environment while recovering valuable salts. However, in the current literature, only a few studies provided limited coverage about the optimization of a continuous MDC process performance with regard to supersaturated solutions. Selecting proper operational conditions for process control is necessary, as there is a need to prevent membrane wetting and crystal crystallization within the membrane module due to concentration and temperature polarization effects. As such, the concept of fractional experimental design was introduced to determine the optimum operational parameters. Results from the analysis were verified experimentally, and it was deduced that a feed flow rate and temperature of 0.64 L/min and 338 K respectively, together with a permeate flow rate of 0.35 L/min and permeate temperature of 303 K, gave the highest production rates of pure water and sodium chloride crystals. In addition, a runtime experiment lasting 21 hours was performed to determine its viability to be implemented on an industrial scale. Results showed the deterioration of the process performance and the quality of the permeate fluid worsening over time. Further analysis revealed that it was due to surface modifications on the membranes as a result of prolonged contact with high temperatures and a highly concentrated solution. Therefore, this implies the need for fabrication of membranes specially designed for continuous MDC processes operating in supersaturated solutions. Bachelor of Engineering (Environmental Engineering) 2013-05-29T01:48:52Z 2013-05-29T01:48:52Z 2013 2013 Final Year Project (FYP) http://hdl.handle.net/10356/52871 en Nanyang Technological University 31 p. application/pdf |
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DRNTU::Engineering::Environmental engineering::Water treatment Lim, Deric Weikang. Optimization of operational conditions for continuous membrane distillation crystallization process with zero discharge |
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Membrane Distillation Crystallization (MDC) is an innovative approach which involves the integration of the Membrane Distillation (MD) process together with a crystallizer unit. By tapping onto the potentials of MD, it becomes possible to operate under a supersaturated state of the solution, thereby achieving the objective of zero discharge to the environment while recovering valuable salts. However, in the current literature, only a few studies provided limited coverage about the optimization of a continuous MDC process performance with regard to supersaturated solutions. Selecting proper operational conditions for process control is necessary, as there is a need to prevent membrane wetting and crystal crystallization within the membrane module due to concentration and temperature polarization effects. As such, the concept of fractional experimental design was introduced to determine the optimum operational parameters. Results from the analysis were verified experimentally, and it was deduced that a feed flow rate and temperature of 0.64 L/min and 338 K respectively, together with a permeate flow rate of 0.35 L/min and permeate temperature of 303 K, gave the highest production rates of pure water and sodium chloride crystals.
In addition, a runtime experiment lasting 21 hours was performed to determine its viability to be implemented on an industrial scale. Results showed the deterioration of the process performance and the quality of the permeate fluid worsening over time. Further analysis revealed that it was due to surface modifications on the membranes as a result of prolonged contact with high temperatures and a highly concentrated solution. Therefore, this implies the need for fabrication of membranes specially designed for continuous MDC processes operating in supersaturated solutions. |
| author2 |
Wang Rong |
| author_facet |
Wang Rong Lim, Deric Weikang. |
| format |
Final Year Project |
| author |
Lim, Deric Weikang. |
| author_sort |
Lim, Deric Weikang. |
| title |
Optimization of operational conditions for continuous membrane distillation crystallization process with zero discharge |
| title_short |
Optimization of operational conditions for continuous membrane distillation crystallization process with zero discharge |
| title_full |
Optimization of operational conditions for continuous membrane distillation crystallization process with zero discharge |
| title_fullStr |
Optimization of operational conditions for continuous membrane distillation crystallization process with zero discharge |
| title_full_unstemmed |
Optimization of operational conditions for continuous membrane distillation crystallization process with zero discharge |
| title_sort |
optimization of operational conditions for continuous membrane distillation crystallization process with zero discharge |
| publishDate |
2013 |
| url |
http://hdl.handle.net/10356/52871 |
| _version_ |
1759857952213172224 |