Performance assessment of a marine freshwater generator through exergetic optimization
Performance assessment of a marine freshwater generator through exergetic optimization
The objective of this study is to examine the effect of operating parameters on the freshwater generation capacity of a vacuum type and low-temperature single-stage freshwater generator and the exergy destruction of the condenser and evaporator sections. Evaporator and condenser, which are plate type heat exchangers, are modeled using the ε-NTU method. Energy and exergy analyses were applied to the control volume enclosing the condenser and evaporator to find the freshwater production rate and to investigate the system performance. A parametric study was performed to assess the effects of the jacket water mass flow rate, the seawater salinity, and the seawater temperature on the output parameters (fresh water production rate and specific exergy destruction). In addition, an optimization study was performed using the Taguchi method to maximize the freshwater production rate and minimize the exergy destruction rates of the condenser and evaporator. The results derived from the parametric study showed that the seawater temperature of 31.88 °C and jacket water mass flow rate of 72,000 kg/h are the required values to obtain the maximum freshwater generation capacity (30 m 3 /day). When the salinity increases from 3 g/kg to 41 g/kg (3000 to 41,000 ppm), the freshwater production rate increases by 2.18% and 5.06% under the constant seawater temperature (23 °C) and the jacket water mass flow rate (58,500 kg/h), respectively. The optimization results revealed the conditions to obtain the maximum fresh water production rate and the minimum exergy destruction.
Desalination, Exergy analysis, Heat exchanger, Taguchi method, Waste heat
326-335
Yuksel, Onur
5138ebb7-a0f3-4308-907c-5baf1dd35360
Gulmez, Yigit
36a3b6c6-bedc-4d14-afe0-e28d84c4fa9e
Konur, Olgun
4d099dab-c4ae-4baa-a93a-cf6471c304e6
Korkmaz, S. Aykut
959074e1-2ec0-405c-b1ec-eeababef216b
Erdogan, Anil
44025ece-41a7-44a9-ae20-b441af3fa2d7
Colpan, C. Ozgur
b3fce544-afd7-4815-a5cb-d947797a9dbc
15 February 2019
Yuksel, Onur
5138ebb7-a0f3-4308-907c-5baf1dd35360
Gulmez, Yigit
36a3b6c6-bedc-4d14-afe0-e28d84c4fa9e
Konur, Olgun
4d099dab-c4ae-4baa-a93a-cf6471c304e6
Korkmaz, S. Aykut
959074e1-2ec0-405c-b1ec-eeababef216b
Erdogan, Anil
44025ece-41a7-44a9-ae20-b441af3fa2d7
Colpan, C. Ozgur
b3fce544-afd7-4815-a5cb-d947797a9dbc
Yuksel, Onur, Gulmez, Yigit, Konur, Olgun, Korkmaz, S. Aykut, Erdogan, Anil and Colpan, C. Ozgur
(2019)
Performance assessment of a marine freshwater generator through exergetic optimization.
Journal of Cleaner Production, 219, .
(doi:10.1016/j.jclepro.2019.02.083).
Abstract
The objective of this study is to examine the effect of operating parameters on the freshwater generation capacity of a vacuum type and low-temperature single-stage freshwater generator and the exergy destruction of the condenser and evaporator sections. Evaporator and condenser, which are plate type heat exchangers, are modeled using the ε-NTU method. Energy and exergy analyses were applied to the control volume enclosing the condenser and evaporator to find the freshwater production rate and to investigate the system performance. A parametric study was performed to assess the effects of the jacket water mass flow rate, the seawater salinity, and the seawater temperature on the output parameters (fresh water production rate and specific exergy destruction). In addition, an optimization study was performed using the Taguchi method to maximize the freshwater production rate and minimize the exergy destruction rates of the condenser and evaporator. The results derived from the parametric study showed that the seawater temperature of 31.88 °C and jacket water mass flow rate of 72,000 kg/h are the required values to obtain the maximum freshwater generation capacity (30 m 3 /day). When the salinity increases from 3 g/kg to 41 g/kg (3000 to 41,000 ppm), the freshwater production rate increases by 2.18% and 5.06% under the constant seawater temperature (23 °C) and the jacket water mass flow rate (58,500 kg/h), respectively. The optimization results revealed the conditions to obtain the maximum fresh water production rate and the minimum exergy destruction.
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More information
Accepted/In Press date: 8 February 2019
e-pub ahead of print date: 10 February 2019
Published date: 15 February 2019
Keywords:
Desalination, Exergy analysis, Heat exchanger, Taguchi method, Waste heat
Identifiers
Local EPrints ID: 487099
URI: http://eprints.soton.ac.uk/id/eprint/487099
ISSN: 0959-6526
PURE UUID: cf368ba3-4eb9-4108-a1af-828deaaecb1d
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Date deposited: 13 Feb 2024 17:32
Last modified: 06 Jun 2024 02:19
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Contributors
Author:
Onur Yuksel
Author:
Yigit Gulmez
Author:
Olgun Konur
Author:
S. Aykut Korkmaz
Author:
Anil Erdogan
Author:
C. Ozgur Colpan
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