PartagerUnité de refroidissement pour le projet AmpaCity : un an de succès opérationnel.
Cooling unit for the AmpaCity project – One year successful operation.
Auteurs : HERZOG F., KUTZ T., STEMMLE M., et al.
Type d'article : Article, Étude de cas
Résumé
High temperature super conductors (HTS) can efficiently be cooled with liquid nitrogen down to a temperature of 64 K (-209°C). Lower temperatures are not practical, because at 63 K (-210°C) nitrogen becomes solid. To achieve this temperature level the coolant has to be vaporized below atmospheric pressure. Messer has developed a cooling unit with an adequate vacuum subcooler, a liquid nitrogen circulation system, and a storage vessel for cooling an HTS-power cable. Liquid nitrogen is circulated through the superconducting cable to take out the heat, and afterward it is pumped through the subcooler to be recooled. In the circulation system liquid nitrogen is used as a dielectric fluid and as a heat transfer medium. It stays always liquid (subcooled) and does not vaporize. On the secondary side of the subcooler liquid nitrogen from the storage vessel is used as refrigerant. It is vaporized under a pressure of 150 mbar to achieve the desired low temperatures. The cooling unit was delivered in 2013 for the German AmpaCity project of RWE Deutschland AG, Nexans and Karlsruhe Institute of Technology. Within this project RWE and Nexans installed the worldwide longest superconducting power cable in the city of Essen, Germany. The cooling unit cools a 10 kV concentric HTS cable (40 MV A) with a length of 1000 m. The cable is in operation since March 10th, 2014. After more than one year of practical operation many important figures from cable and cooling unit are available. These figures are discussed and a total energy balance is shown to compare liquid nitrogen cooling with alternative mechanical cooling systems.
Détails
- Titre original : Cooling unit for the AmpaCity project – One year successful operation.
- Identifiant de la fiche : 30020894
- Langues : Anglais
- Source : Cryogenics - vol. 80
- Date d'édition : 04/2016
- DOI : http://dx.doi.org/10.1016/j.cryogenics.2016.04.001
Liens
Voir d'autres articles du même numéro (31)
Voir la source
Indexation
- Thèmes : Supraconduction
- Mots-clés : Câble supraconducteur; Allemagne; Azote liquide; Refroidissement; Puissance; Étude de cas
-
Cryogenic system design for HTS power transmiss...
- Auteurs : FAN Y. F., ZHANG L., GONG L. H., et al.
- Date : 22/04/2003
- Langues : Anglais
- Source : Cryogenics and refrigeration. Proceedings of ICCR 2003.
Voir la fiche
-
Feasibility of inline cooling in long distance ...
- Auteurs : ZAJACZKOWSKI B., GIESBERS A.J.M., HOLTRUST M., et al.
- Date : 04/2011
- Langues : Anglais
- Source : Cryogenics - vol. 51 - n. 4
Voir la fiche
-
Cryogenic technologies of the superconducting N...
- Auteurs : AGAPOV N., KHODZHIBAGIYAN H., KONSTANTINOV A., et al.
- Date : 08/05/2019
- Langues : Anglais
- Source : Cryogenics 2019. Proceedings of the 15th IIR International Conference: Prague, Czech Republic, April 8-11, 2019.
- Formats : PDF
Voir la fiche
-
Cooling unit for superconducting electricity ca...
- Auteurs : HERZOG F., KUTZ T.
- Date : 07/04/2014
- Langues : Anglais
- Source : Cryogenics 2014. Proceedings of the 13th IIR International Conference: Prague, Czech Republic, April 7-11, 2014.
- Formats : PDF
Voir la fiche
-
Cryogenic tests of the main HTS current leads f...
- Auteurs : DATSKOV V., FISCHER E., BLEILE A., et al.
- Date : 08/05/2019
- Langues : Anglais
- Source : Cryogenics 2019. Proceedings of the 15th IIR International Conference: Prague, Czech Republic, April 8-11, 2019.
- Formats : PDF
Voir la fiche