Geothermal waters heat integration for the desalination of sea water
Identifieur interne : 000006 ( PascalFrancis/Corpus ); précédent : 000005; suivant : 000007Geothermal waters heat integration for the desalination of sea water
Auteurs : C. Koroneos ; G. RoumbasSource :
- Desalination and water treatment : (Print) [ 1944-3994 ] ; 2012.
Descripteurs français
- Pascal (Inist)
- Dessalement, Eau mer, Distillation multiple effet, Consommation énergie, Hydrocarbure, Impact environnement, Eau douce, Cycle vie (environnement), Analyse avantage coût, Coût global, Centrale(production énergie), Centrale dessalement, Qualité eau, Energie renouvelable, Eau potable, Mer Egée, Protection environnement, Développement durable.
English descriptors
- KwdEn :
- Aegean Sea, Cost benefit analysis, Desalination, Desalination plant, Drinking water, Energy consumption, Environment impact, Environmental protection, Fresh water, Hydrocarbon, Life cycle (environment), Life cycle cost, Multiple effect distillation, Power plant, Renewable energy, Seawater, Sustainable development, Water quality.
Abstract
The main objective of this work is to utilize the existing geothermal potential of the Greek island of Nisyros located in the southeastern part of the Aegean Sea for desalination of seawater. The technology most applicable for the exploitation of geothermal purposes is the multiple effect distillation process (MED). The exploitation of the geothermal hot water sources located in the island combined with an effective desalination technology can eliminate energy consumption from hydrocarbons, minimize the environmental impact and reduce dramatically the cost of fresh water. The determination of the overall environmental impact of the desalination plan by means of a Life Cycle Analysis, and the evaluation of the measure's economical feasibility by means of Cost-Benefit Analysis and Life Cycle Cost methods will be shown. Exergy Analysis of the process will determine its thermodynamic efficiency. This work is to determine and demonstrate the feasibility of a geothermal-driven power-desalination plant to provide high quality of water in sufficient quantity at affordable costs, while protecting the fragile island environment.
Notice en format standard (ISO 2709)
Pour connaître la documentation sur le format Inist Standard.
pA |
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Format Inist (serveur)
NO : | PASCAL 12-0196944 INIST |
---|---|
ET : | Geothermal waters heat integration for the desalination of sea water |
AU : | KORONEOS (C.); ROUMBAS (G.) |
AF : | Laboratory of Heat Transfer and Environmental Engineering, Aristotle University of Thessaloniki P.O. Box 483/Thessaloniki 54124/Grèce (1 aut., 2 aut.) |
DT : | Publication en série; Niveau analytique |
SO : | Desalination and water treatment : (Print); ISSN 1944-3994; Italie; Da. 2012; Vol. 37; No. 1-3; Pp. 69-76; Bibl. 16 ref. |
LA : | Anglais |
EA : | The main objective of this work is to utilize the existing geothermal potential of the Greek island of Nisyros located in the southeastern part of the Aegean Sea for desalination of seawater. The technology most applicable for the exploitation of geothermal purposes is the multiple effect distillation process (MED). The exploitation of the geothermal hot water sources located in the island combined with an effective desalination technology can eliminate energy consumption from hydrocarbons, minimize the environmental impact and reduce dramatically the cost of fresh water. The determination of the overall environmental impact of the desalination plan by means of a Life Cycle Analysis, and the evaluation of the measure's economical feasibility by means of Cost-Benefit Analysis and Life Cycle Cost methods will be shown. Exergy Analysis of the process will determine its thermodynamic efficiency. This work is to determine and demonstrate the feasibility of a geothermal-driven power-desalination plant to provide high quality of water in sufficient quantity at affordable costs, while protecting the fragile island environment. |
CC : | 001D16A |
FD : | Dessalement; Eau mer; Distillation multiple effet; Consommation énergie; Hydrocarbure; Impact environnement; Eau douce; Cycle vie (environnement); Analyse avantage coût; Coût global; Centrale(production énergie); Centrale dessalement; Qualité eau; Energie renouvelable; Eau potable; Mer Egée; Protection environnement; Développement durable |
FG : | Mer Méditerranée; Composé organique |
ED : | Desalination; Seawater; Multiple effect distillation; Energy consumption; Hydrocarbon; Environment impact; Fresh water; Life cycle (environment); Cost benefit analysis; Life cycle cost; Power plant; Desalination plant; Water quality; Renewable energy; Drinking water; Aegean Sea; Environmental protection; Sustainable development |
EG : | Mediterranean Sea; Organic compounds |
SD : | Desaladura; Agua mar; Destilación efecto múltiple; Consumo energía; Hidrocarburo; Impacto medio ambiente; Agua dulce; Ciclo vida (medio ambiente); Análisis coste beneficio; Costo global; Central eléctrica; Central desaladura; Calidad agua; Energía renovable; Agua potable; Mar Egeo; Protección medio ambiente; Desarrollo sostenible |
LO : | INIST-28018.354000509267170090 |
ID : | 12-0196944 |
Links to Exploration step
Pascal:12-0196944Le document en format XML
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<front><div type="abstract" xml:lang="en">The main objective of this work is to utilize the existing geothermal potential of the Greek island of Nisyros located in the southeastern part of the Aegean Sea for desalination of seawater. The technology most applicable for the exploitation of geothermal purposes is the multiple effect distillation process (MED). The exploitation of the geothermal hot water sources located in the island combined with an effective desalination technology can eliminate energy consumption from hydrocarbons, minimize the environmental impact and reduce dramatically the cost of fresh water. The determination of the overall environmental impact of the desalination plan by means of a Life Cycle Analysis, and the evaluation of the measure's economical feasibility by means of Cost-Benefit Analysis and Life Cycle Cost methods will be shown. Exergy Analysis of the process will determine its thermodynamic efficiency. This work is to determine and demonstrate the feasibility of a geothermal-driven power-desalination plant to provide high quality of water in sufficient quantity at affordable costs, while protecting the fragile island environment.</div>
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<server><NO>PASCAL 12-0196944 INIST</NO>
<ET>Geothermal waters heat integration for the desalination of sea water</ET>
<AU>KORONEOS (C.); ROUMBAS (G.)</AU>
<AF>Laboratory of Heat Transfer and Environmental Engineering, Aristotle University of Thessaloniki P.O. Box 483/Thessaloniki 54124/Grèce (1 aut., 2 aut.)</AF>
<DT>Publication en série; Niveau analytique</DT>
<SO>Desalination and water treatment : (Print); ISSN 1944-3994; Italie; Da. 2012; Vol. 37; No. 1-3; Pp. 69-76; Bibl. 16 ref.</SO>
<LA>Anglais</LA>
<EA>The main objective of this work is to utilize the existing geothermal potential of the Greek island of Nisyros located in the southeastern part of the Aegean Sea for desalination of seawater. The technology most applicable for the exploitation of geothermal purposes is the multiple effect distillation process (MED). The exploitation of the geothermal hot water sources located in the island combined with an effective desalination technology can eliminate energy consumption from hydrocarbons, minimize the environmental impact and reduce dramatically the cost of fresh water. The determination of the overall environmental impact of the desalination plan by means of a Life Cycle Analysis, and the evaluation of the measure's economical feasibility by means of Cost-Benefit Analysis and Life Cycle Cost methods will be shown. Exergy Analysis of the process will determine its thermodynamic efficiency. This work is to determine and demonstrate the feasibility of a geothermal-driven power-desalination plant to provide high quality of water in sufficient quantity at affordable costs, while protecting the fragile island environment.</EA>
<CC>001D16A</CC>
<FD>Dessalement; Eau mer; Distillation multiple effet; Consommation énergie; Hydrocarbure; Impact environnement; Eau douce; Cycle vie (environnement); Analyse avantage coût; Coût global; Centrale(production énergie); Centrale dessalement; Qualité eau; Energie renouvelable; Eau potable; Mer Egée; Protection environnement; Développement durable</FD>
<FG>Mer Méditerranée; Composé organique</FG>
<ED>Desalination; Seawater; Multiple effect distillation; Energy consumption; Hydrocarbon; Environment impact; Fresh water; Life cycle (environment); Cost benefit analysis; Life cycle cost; Power plant; Desalination plant; Water quality; Renewable energy; Drinking water; Aegean Sea; Environmental protection; Sustainable development</ED>
<EG>Mediterranean Sea; Organic compounds</EG>
<SD>Desaladura; Agua mar; Destilación efecto múltiple; Consumo energía; Hidrocarburo; Impacto medio ambiente; Agua dulce; Ciclo vida (medio ambiente); Análisis coste beneficio; Costo global; Central eléctrica; Central desaladura; Calidad agua; Energía renovable; Agua potable; Mar Egeo; Protección medio ambiente; Desarrollo sostenible</SD>
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