Exergy costs analysis of water desalination and purification techniques by transfer functions

Energy Conversion and Management

Volumn 126, Issue , 2016, Pages 51-59

  Carrasquer, Beatriz ^a   Martínez Gracia, Amaya ^a   Uche, Javier ^a  

^a UNIVERSITY OF ZARAGOZA   (Spain)

Author keywords

Desalination; Exergy analysis; Exergy cost; Transfer functions; Water costs; Water treatment

Indexed keywords

BIOGEOCHEMISTRY; BIOLOGICAL MATERIALS; CHEMICALS REMOVAL (WATER TREATMENT); COSTS; DESALINATION; DISTILLATION; ENERGY EFFICIENCY; EXERGY; GROUNDWATER; MEMBRANE TECHNOLOGY; ORGANIC COMPOUNDS; PURIFICATION; RECOVERY; SALTS; TRANSFER FUNCTIONS; WATER FILTRATION; WATER SUPPLY; WATER TREATMENT; WATER TREATMENT PLANTS;

DISTILLATION PROCESS; EXERGY ANALYSIS; EXERGY COST; ORGANIC MATTER RECOVERIES; PURIFICATION TECHNIQUES; TRANSFER FUNCTION ANALYSIS; WATER COSTS; WATER TREATMENT PROCESS;

COST BENEFIT ANALYSIS;

EID: 84980332062     PISSN: 01968904     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.enconman.2016.07.065     Document Type: Article

References (53)

1. [1] Panepinto, D., Fiore, S., Zappone, M.A., Genon, G., Meucci, L., Evaluation of the energy efficiency of a large wastewater treatment plant in Italy. Appl Energy 161 (2016), 404–411, 10.1016/j.apenergy.2015.10.027.
2. [2] Flores-Alsina, X., Corominas, L., Snip, L., Vanrolleghem, P.A., Including greenhouse gas emissions during benchmarking of wastewater treatment plant control strategies. Water Res 45:16 (2011), 4700–4710, 10.1016/j.watres.2011.04.040.
3. [3] Sweetapple, C., Fu, G., Butler, D., Multi-objective optimisation of wastewater treatment plant control to reduce greenhouse gas emissions. Water Res 55C (2014), 52–62, 10.1016/j.watres.2014.02.018.
4. [4] Corominas, L.l., Foley, J., Guest, J.S., Hospido, A., Larsen, H.F., Morera, S., et al. Life cycle assessment applied to wastewater treatment: state of the art. Water Res 47 (2013), 5480–5492, 10.1016/j.watres.2013.06.049.
5. [5] Yoshida, H., Clavreul, J., Scheutz, C., Christensen, T.H., Influence of data collection schemes on the life cycle assessment of a municipal wastewater treatment plant. Water Res 56 (2014), 292–303, 10.1016/j.watres.2014.03.014.
6. [6] Meneses, M., Concepción, H., Vrecko, D., Vilanova, R., Life cycle assessment as an environmental evaluation tool for control strategies in wastewater treatment plants. J Clean Prod 107 (2015), 653–661, 10.1016/j.jclepro.2015.05.057.
7. [7] Ahmadi, A., Tiruta-Barna, L., A process modelling-life cycle assessment-multiobjective optimization tool for the eco-design of conventional treatment processes of potable water. J Clean Prod 100 (2015), 116–125, 10.1016/j.jclepro.2015.03.045.
8. [8] Zeng, J., Liu, J., Economic model predictive control of wastewater treatment processes. Ind Eng Chem Res 54 (2015), 5710–5721, 10.1021/ie504995n.
9. [9] Hreiz, R., Roche, N., Benyahia, B., Latifi, M.A., Multi-objective optimal control of small size waste water treatment plants. Chem Eng Res Des 102 (2015), 345–353, 10.1016/j.cherd.2015.06.039.
10. [10] Eveloy, V., Rodgers, P., Qiu, L., Hybrid gas turbine–organic Rankine cycle for seawater desalination by reverse osmosis in a hydrocarbon production facility. Energy Convers Manage 106 (2015), 1134–1148, 10.1016/j.enconman.2015.10.019.
11. [11] Jiang, A., Biegler, L.T., Wang, J., Cheng, W., Ding, Q., Jiangzhou, S., Optimal operations for large-scale seawater reverse osmosis networks. J Membr Sci 476 (2015), 508–524, 10.1016/j.memsci.2014.12.005.
12. [12] Lin, S., Elimelech, M., Staged reverse osmosis operation: configurations, energy efficiency, and application potential. Desalination 366 (2015), 9–14, 10.1016/j.desal.2015.02.043.
13. [13] Al-Nory, M.T., Brodsky, A., Bozkaya, B., Graves, S.C., Desalination supply chain decision analysis and optimization. Desalination 347 (2014), 144–157, 10.1016/j.desal.2014.05.037.
14. [14] Boroumandjazi, G., Rismanchi, B., Saidur, R., A review of exergy analysis of industrial sector. Renew Sustain Energy Rev 27 (2013), 198–203, 10.1016/j.rser.2005.11.006.
15. [15] Gräbner, M., Meyer, B., Performance and exergy analysis of the current developments in coal gasification technology. Fuel 116 (2014), 910–920, 10.1016/j.fuel.2013.02.045.
16. [16] Boateng, A.A., Mullen, C.H., Osgood-Jacobs, L., Carlson, P., Macken, N., Mass balance, energy, and exergy analysis of bio-oil production by fast pyrolysis. J Energy Res Technol 134 (2012), 042001-1–042001-9, 10.1115/1.4007659.
17. [17] Al-Ghandoor, A.G., ALSalaymeh, M., Al-Abdallat, Y., Rawashdeh, M., Energy and exergy utilizations of the Jordanian SMEs industries. Energy Convers Manage 65 (2013), 682–687, 10.1016/j.enconman.2011.11.036.
18. [18] Sui, X., Zhang, Y., Shao, S., Zhang, S., Exergetic life cycle assessment of cement production process with waste heat power generation. Energy Convers Manage 88 (2014), 684–692, 10.1016/j.enconman.2014.08.035.
19. [19] Adem Atmaca, A., Yumrutas, R., Thermodynamic and exergoeconomic analysis of a cement plant: Part II – Application. Energy Convers Manage 79 (2014), 799–808, 10.1016/j.enconman.2013.11.054.
20. [20] Yilmaz, C., Kanoglu, M., Abusoglu, A., Thermoeconomic cost evaluation of hydrogen production driven by binary geothermal power plant. Geothermics 57 (2015), 18–25, 10.1016/j.geothermics.2015.05.005.
21. [21] Tan, M., Kecebas, A., Thermodynamic and economic evaluations of a geothermal district heating system using advanced exergy-based methods. Energy Convers Manage 77 (2014), 504–513, 10.1016/j.enconman.2013.10.006.
22. [22] Memona, A.G., Memona, R.A., Harijan, K., Uqaili, M.A., Parametric based thermo-environmental and exergoeconomic analyses of a combined cycle power plant with regression analysis and optimization. Energy Convers Manage 92 (2015), 19–35, 10.1016/j.enconman.2014.12.033.
23. [23] Siddiqui, F.R., El-Shaarawi, M.A.I., Said, S.A.M., Exergo-economic analysis of a solar driven hybrid storage absorption refrigeration cycle. Energy Convers Manage 80 (2014), 165–172, 10.1016/j.enconman.2014.01.029.
24. [24] Fortunato, B., Torresi, M., Deramo, A., Modeling, performance analysis and economic feasibility of a mirror-augmented photovoltaic system. Energy Convers Manage 80 (2014), 276–286, 10.1016/j.enconman.2013.12.074.
25. [25] Al-Sulaiman, Fahad A., Yilbas, Bekir S., Thermoeconomic analysis of shrouded wind turbines. Energy Convers Manage 96 (2015), 599–604, 10.1016/j.enconman.2015.02.034.
26. [26] Nguyen, C., Veje, C.T., Willatzen, M., Andersen, P., Exergy costing for energy saving in combined heating and cooling applications. Energy Convers Manage 86 (2014), 349–355, 10.1016/j.enconman.2014.05.040.
27. [27] Wang, M., Khalilpour, R., Abbas, A., Thermodynamic and economic optimization of LNG mixed refrigerant processes. Energy Convers Manage 88 (2014), 947–961, 10.1016/j.enconman.2014.09.007.
28. [28] Shokati, N., Ranjbar, F., Yari, M., Exergoeconomic analysis and optimization of basic, dual-pressure and dual-fluid ORCs and Kalina geothermal power plants: a comparative study. Renew Energy 83 (2015), 527–542, 10.1016/j.renene.2015.04.069.
29. [29] Martínez, A., Uche, J., Rubio, C., Carrasquer, B., Exergy cost of water supply and water treatment technologies. Desalinat Water Treat 24 (2010), 123–131, 10.5004/dwt.2010.1368.
30. [30] Valero, A., Uche, J., Valero, A., Martínez, A., Physical hydronomics: application of the exergy analysis to the assessment of environmental costs of water bodies. The case of the inland basins of Catalonia. Energy 34:12 (2009), 2101–2107, 10.1016/j.energy.2008.08.020.
31. [31] Martínez, A., Uche, J., Valero, A., Valero, Al, Environmental costs of a river watershed within the European water framework directive: results from physical hydronomics. Energy 35 (2010), 1008–1016, 10.1016/j.energy.2009.06.026.
32. [32] Uche, J., Martínez, A., Carrasquer, B., Exergy as a guide to allocate environmental costs for implementing the water framework directive in the ebro river. Desalinat Water Treat 51 (2013), 4207–4217, 10.1080/19443994.2013.768047.
33. [33] Abusoglu, A., Demir, S., Kanoglu, M., Thermoeconomic assessment of a sustainable municipal wastewater treatment system. Renew Energy 48 (2012), 424–435, 10.1016/j.renene.2012.06.005.
34. [34] Khosravi, S., Panjeshahi, M.H., Ataei, A., Application of exergy analysis for quantification and optimisation of the environmental performance in wastewater treatment plants. Int J Exergy 12 (2013), 110–138, 10.1504/IJEX.2013.052552.
35. [35] Cerci Y, Cengel Y, Wood B, Kahraman N, Karakas ES. Improving the thermodynamic and economic efficiencies of desalination plants: minimum work required for desalination and case studies of four working plants. In: Mechanical Engineering, University of Nevada. Reno, Nevada. Desalination and water purification research and development program; 2003; Final report no. 78.
36. [36] Mistry, K., McGovern, R., Thiel, G., Summers, E., Entropy generation analysis of desalination technologies. Entropy 13 (2011), 1829–1864, 10.3390/e13101829.
37. [37] Jin, C., Chou, Q., Jiao, D., Shu, P., Vapour compression Flash seawater desalination system and its exergy analysis. Desalination 353 (2014), 75–83, 10.1016/j.desal.2014.09.001.
38. [38] Esfahani, I.J., Lee, S., Yoo, C., Evaluation and optimization of a multi-effect evaporation-absorption heat pump desalination based conventional and advanced exergy and exergoeconomic analyses. Desalination 359 (2015), 92–107, 10.1016/j.desal.2014.12.030.
39. [39] Piacentino, A., Application of advanced thermodynamics, thermoeconomics and exergy costing to a multiple effect distillation plant: in-depth analysis of cost formation process. Desalination 371 (2015), 88–103, 10.1016/j.desal.2015.06.008.
40. [40] El–Emam, R.S., Dincer, I., Thermodynamic and thermoeconomic analyses of seawater reverse osmosis desalination plant with energy recovery. Energy 64 (2014), 154–163, 10.1016/j.energy.2013.11.037.
41. [41] Valero A, Lozano M, Muñoz MA. A general theory of exergy savings. Part I: on the exergy costs, part II: on the thermoeconomic cost, part III: energy savings and thermoeconomics. In: Gaggioli R, editor. Computer-aided engineering of energy systems, ASME Book H0341C, vol. 2–3. New York; 1986., p. 1–21.
42. [42] Lozano, M.A., Valero, A., Theory of exergetic cost. Energy 18 (1993), 939–960, 10.1016/0360-5442(93)90006-Y.
43. [43] Carrasquer, B., Uche, J., Martínez-Gracia, A., Exergy costs analysis of groundwater use and water transfers. Energy Convers Manage 110 (2016), 419–427, 10.1016/j.enconman.2015.12.022.
44. [44] Zaleta, A., Ranz, L., Valero, A., Towards a unified measure of renewable resources availability: the exergy method applied to the water of a river. Energy Convers Manage 39:16-18 (1998), 1911–1917, 10.1016/S0196-8904(98)00091-0.
45. [45] Martínez, A., Uche, J., Chemical exergy assessment of organic matter in a water flow. Energy 35:1 (2010), 77–84, 10.1016/j.energy.2009.08.032.
46. [46] Perry, R.H., Green, D.W., Perry, Manual del Ingeniero Químico. Séptima edición, 2001, McGraw Hill ISBN 84.481-3008-1.
47. [47] Tai, S., Matsushige, K., Goda, T., Chemical exergy of organic matter in wastewater. Int J Environ Stud, 1986.
48. [48] Stanford University. Transfer function analysis. Available online. < ccrma.stanford.edu> [last accessed: October, 2014].
49. [49] Instituto para la Diversificación y Ahorro de la Energía (IDAE), Estudio de prospectiva. Consumo energético en el sector del agua. Fundación OPTI. Ministerio de Industria, turismo y comercio. Gobierno de España. 2010 [in Spanish].
50. [50] Peñate, B., Círez, F., Domínguez, F.J., Subiela, V.J., Vera, L., Design and testing of an isolated commercial EDR plant driven by solar photovoltaic energy. Desalinat Water Treat 51 (2013), 1254–1264.
51. [51] Lozano-García, A.I., Análisis exergético en plantas de tratamiento en el ciclo integral del agua. Proyecto final de Máster de Energías Renovables y Eficiencia Energética, 2011, CIRCE-Universidad de Zaragoza.
52. [52] Consorci Costa Brava (CCB). Datos plantas saneamiento. Available online. < http://www.ccbgi.org/sanejament/> [last accessed: February, 2014].
53. [53] Rodriguez-Garcia, G., Molinos-Senante, M., Hospido, A., Hernández-Sancho, F., Moreira, M.T., Feijoo, M.T., Environmental and economic profile of six typologies of wastewater treatment plants. Water Res 45:18 (2011), 5997–6010, 10.1016/j.watres.2011.08.053.