Top

Hint

Swipe to navigate through the chapters of this book

Published in:

Read chapter Read first chapter

2021 | OriginalPaper | Chapter

7. Industrielle Nutzung von Gashydraten

Author: Judith M. Schicks

Published in: Gashydrate – Eine Einführung in Grundlagenforschung und Anwendung

Publisher: Springer Berlin Heidelberg

Zusammenfassung

In Kap. 7 werden verschiedene potentielle Anwendungsbereiche für die Nutzung von Gashydraten vorgestellt. Dazu gehören die Speicherung und der Transport von Erdgas und Wasserstoff in Gashydraten, die Speicherung von Kohlenstoffdioxid in Gashydraten als Alternative zur geologischen Speicherung, die Reinigung und Separation von Gasen, die Meerwasserentsalzung und Abwasseraufbereitung sowie der Einsatz von Gashydraten als Kältemittel in Kühlkreisläufen.

previous chapter Gewinnung von Erdgas durch den Abbau natürlicher Gashydratvorkommen

next chapter Zersetzung natürlicher Gashydratvorkommen: potentielle Folgen für Hangstabilitäten und Klima

Babu P, Nambiar A, He T, Karimi IA, Lee JD, Englezos P, Linga P (2018) A review of clathrate hydrate based desalination to strengthen energy – water nexus. ACS Sustain Chem Eng 6:8093–8107 CrossRef

Cheng C, Wang F, Tian Y, Wu X, Zheng J, Zhang J, Li L, Yang P, Zhao J (2020) Review and prospects of hydrate cold storage technology. Renew Sust Energ Rev 117:109492 CrossRef

Fitzgerald A, Taylor M (2001) Offshore gas-to-solids technology. In: Proceedings of offshore Europe conference, Aberdeen, UK, 2001, SPE 71805

Fournaison L, Delahaye A, Chatti I, Petitet J-P (2004) CO ₂ Hydrates in refrigeration processes. Ind Eng Chem Res 43:6521–6526 CrossRef

Gerling JP, Reinhold K, Knopf S (2009) Speicherpotenziale für CO ₂ in Deutschland. In: Die dauerhafte geologische Speicherung von CO ₂ in Deutschland – Aktuelle Forschungsergebnisse und Perspektiven. Herausgeber: L. Stroink, JP Gerling, M. Kühn und F. Schilling, Geotechnologien Science Report, No. 14. 28–39, Koordinierungsbüro Geotechnologien, Potsdam

Grim RG, Barnes BC, Lafond PG, Kockelmann WA, Keen DA, Soper AK, Hiratsuka M, Yasuoka K, Koh CA, Sum AK (2014) Observation of Interstitial Molecular Hydrogen in Clathrate Hydrates. Angew. Chem. Int. Ed. 53:10710–10713

Hassanpouryouzband A, Joonaki E, Vasheghani Farahani M, Takeya S, Ruppel C, Yang J, English NJ, Schicks J, Edlmann K, Mehrabian H, Aman ZM, Tohidi B (2020) Gas hydrates in sustainable chemistry. Chem Soc Rev 49:5225–5309 CrossRef

He J, Liu Y, Ma Z, Deng S, Zhao R, Zhao L (2017) A literature research on the performance evaluation of hydrate-based CO ₂ capture and separation process. Energy Procedia 105:4090–4097 CrossRef

Iwasaki T, Katoh Y, Nagamori S, Takahashi S (2005) Continuous natural gas hydrate pellet production (NGHP) by process development unit (PDU). In: Proceedings of the 5th international conference on gas hydrates, Trondheim, Norway, Tapir Academic Press, Trondheim, 13–16 June 2005, Paper No. 4003

Kim DH, Kang KC, Seo SD, Lee SM, Jeong JW, Lee JD (2020) Application of silver nanofluids on kinetics of sulfur hexafluoride gas hydrate formation. J Nanosci Nanotechnol 20:5473–5477 CrossRef

Kishimoto M, Iijima S, Ohmura R (2012) Crystal growth of clathrate hydrate at the interface between seawater and hydrophobic-guest liquid: effect of elevated salt concentration. Ind Eng Chem Res 51:5224–5229 CrossRef

Koide H, Takahashi M, Shindo Y, Tazaki Y, Iijima M, Ito K, Kimura N, Omata K (1997) Hydrate formation in sediments in the sub-seabed disposal of CO ₂. Energy 22:279–283 CrossRef

Kruse D, Arlt W (2010) Abtrennung von Kohlendioxid. In: Feuerlöscher oder Klimakiller? Herausgeber: Deutsche Bunsen-Gesellschaft für Physikalische Chemie, Frankfurt am Main, 32–36

Lee JD, Kang KC, Hong SY, Seo SD (2017) Evaluation of hydrate-based desalination and wastewater treatment. Proceedings of the 9th international conference on gas hydrates, Denver, USA

Mao WL, Mao H-K, Goncharov AF, Struzhkin VV, Guo Q, Hu J, Shu J, Hemley RJ, Somayazulu M, Zhao Y (2002) Hydrogen Clusters in Clathrate Hydrate. Science 297:2247−2249

Modisha PM, Ouma CNM, Garidzirai R, Wasserscheid P, Bessarabov D (2019) The Prospect of Hydrogen Storage Using Liquid Organic Hydrogen Carriers. Energy Fuels 33:2778−2796

Ogawa T, Ito T, Watanabe K, Tahara K, Hiraoka R, Ochiai J, Ohmura R, Mori YH (2006) Development of a novel hydrate-based refrigeration system: a preliminary overview. Appl Therm Eng 26:2157–2167 CrossRef

Prasad PSR, Sugahara T, Sum AK, Sloan ED, Koh CA, (2009) Hydrogen Storage in Double Clathrates with tert-Butylamine Journal of Physical Chemistry A Letters 113:6540–6543

Rehder G, Eckl R, Elfgen M, Falenty A, Hamann R, Kähler N, Kuhs WF, Osterkamp H, Windmeier C (2012) Methane hydrate pellet transport using the self-preservation effect: a techno-economic analysis. Energies 5:2499–2523 CrossRef

Riedel E (1988) Anorganische Chemie. de Gruyter, Berlin, 392–393

Seo Y, Moon D, Lee C, Park J-W, Kim B-S, Lee G-W, Dotel P, Lee J-W, Cha M, Yoon J-H (2015) Equilibrium, kinetics, and spectroscopic studies of SF ₆ hydrate in NaCl electrolyte solution. Environ Sci Technol 49:6045–6050 CrossRef

Strobel TA, Taylor CJ, Hester KC, Dec SF, Koh CA, Miller KT, Sloan ED (2006) Molecular Hydrogen Storage in Binary THF-H2 Clathrate Hydrates. J Phys Chem B, 110:17121–17125

Song Y, Dong H, Yang L, Yang M, Li Y, Ling Z, Zhao J (2015) Hydrate-based heavy metal separation from aqueous solution. Sci Rep 6:21389 CrossRef

Sun D, Englezos P (2017) Determination of CO ₂ storage density in a partially water-saturated lab reservoir containing CH ₄ from injection of captured flue gas by gas hydrate crystallization. Can J Chem Eng 95:69–76 CrossRef

Trueba AT, Radovic´ IR, Zevenbergen JF, Kroon MC, Peters CJ (2012) Kinetics measurements and in situ Raman spectroscopy of formation of hydrogenetetrabutylammonium bromide semi-hydrates. Int J Hydrogen Energy 37:5790–5797

Trueba AT, Radovic IR, Zevenbergen JF, Peters CJ, Kroon MC (2013) Kinetic measurements and in situ Raman spectroscopy study of the formation of TBAF semi-hydrates with hydrogen and carbon dioxideInt J Hydrogen Energy, 38:7326–7334

Veluswamy HP, Kumar R, Linga P (2014) Hydrogen storage in clathrate hydrates: Current state of the art and future directions. Applied Energy 122:112–132

Veluswamy HP, Linga P (2013) Macroscopic kinetics of hydrate formation of mixed hydrates of hydrogen/tetrahydrofuran for hydrogen storage. Int J Hydrogen Energy 38:4587–96

von Stackelberg, M (1949) Feste Gashydrate. Die Naturwissenschaften, 36, 11, 327–333

Watanabe S, Takahashi S, Mizubayashi H, Murata S, Murakami H (2008) A demonstration project of NGH land transportation system. Proceedings of the 6th International Conference on Gas Hydrates (ICGH 2008),Vancouver, British Columbia, Canada

Yang M, Song Y, Jiang L, Zhu N, Liu Y, Zhao Y, Dou B, Li Q (2013) CO ₂ Hydrate formation and dissociation in cooled porous media: a potential technology for CO ₂ capture and storage. Environ Sci Technol 47:9739–9746 CrossRef

Zatzepina O, Pooladi-Darvish M (2012) Storage of CO ₂ as hydrate in depleted gas reservoirs. SPE Reservoir Evaluation & Engineering, SPE-137313-PA, 98–108

Zhong D-L, Wang J-L, Lu Y-Y, Li Z, Yan J (2016) Precombustion CO ₂ capture using a hybrid process of adsorption and gas hydrate formation. Energy 102:621–629 CrossRef

Title: Industrielle Nutzung von Gashydraten
Author: Judith M. Schicks
Publisher: Springer Berlin Heidelberg
Book: Gashydrate – Eine Einführung in Grundlagenforschung und Anwendung
Print ISBN: 978-3-662-62777-8

Electronic ISBN: 978-3-662-62778-5

Copyright Year: 2021
DOI: https://doi.org/10.1007/978-3-662-62778-5_7

Springer Professional

Hint

Swipe to navigate through the chapters of this book

7. Industrielle Nutzung von Gashydraten

Zusammenfassung

Premium Partner

Springer Professional

Hint

Swipe to navigate through the chapters of this book

Zusammenfassung

Please log in to get access to this content

Premium Partner