LIQHYSMES – Liquid H2 and SMES for renewable energy applications

Sander, M.; Brighenti, F; Gehring, R.; Jordan, Thomas; Klaeser, M.; Kraft, D.; Mueller, Robert; Neumann, H.; Schneider, T.; Stern, George

doi:10.1016/j.ijhydene.2014.06.008

“…Although HTSC wire is quite costly and needed huge quantity for SMES coil, it is still price valuable as of power system constancy and low-cost liquid nitrogen refrigeration points of view. Hybrid SMES systems are designed by the combination of SMES and ESS devices [34][35][36]. This causes the increase in system's energy capacity and decline the capacity capital [37].…”

Section: Htsc Magnetic Energy Storage For Power Applicationsmentioning

confidence: 99%

High Temperature Superconductors: Materials and Applications

Hasan

¹

2022

Superconductors

1

0

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A ceramic high temperature superconductor called cuprate was discovered in 1986 by Bednorz and Muller at 135 K critical temperature (Tc). Ladik and Bierman demonstrated the idea of high temperature superconductivity (HTSC) by essential excitation of electrons in one chain of double standard DNA. The cuprates are consisted of stiff, fragile, and hard properties which are considered as the negative impact of cuprates superconductors. With the passage of time such drawback were removed and the cuprate superconductors were made capable for various applications. The breakthrough came in the history of superconductors when the iron based HTSC were discovered in 2006. High temperature H2S superconductors are designed at high pressure and Tc greater than 200 K in 2015. From the time of discovery of HTSC, superconductivity is used in different types of fields such as medical, electrical, magnetic, optics, recording media, microwave and communication devices.

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“…There is a predicted and well-documented incoming shortage of helium for superconducting applications [37][38][39][40][41][42],] and hydrogen as a cryogenic coolant has been envisaged as a viable and more economically justified cooling option for superconducting devices [37]. There are many novel engineering designs that can be made possible by using medium-temperature MgB 2 superconducting wires, as developed originally in Cambridge [43] that include the following; a self-contained fully electric superconducting ship, DC fault current limiters, high DC current homopolar motors, cheaper superconducting MgB 2 magnets for fusion [41], SMES [41][42][43] and MRI systems. Development of liquid hydrogen indirectly cooled MgB 2 superconducting high voltage DC cables especially for computer data centres present ideal candidates for early implementation [44].…”

Section: Hydrogen As a Cryogenmentioning

confidence: 99%

Energy Storage Technology for Decentralised Energy Management: Future Prospects

Glowacki¹,

Hanley²

2016

Energy Management of Distributed Generation Systems

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The chapter provides a comparison of energy storage technologies in decentralised energy systems for energy management. The various costs, advantages and disadvantages of the storage technologies will be considered. System dynamics modelling will be used to analyse energy management within the decentralised renewable and storage systems. Additionally, the integration of hydrogen storage technology and the use of hydrogen as an energy carrier in a decentralised airport scenario will be highlighted and the arising advantages of a decentralised airport using novel electric planes powered by hydrogen are discussed.

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“…There is a predicted and well-documented incoming shortage of helium for superconducting applications [37][38][39][40][41][42],] and hydrogen as a cryogenic coolant has been envisaged as a viable and more economically justified cooling option for superconducting devices [37]. There are many novel engineering designs that can be made possible by using medium-temperature MgB 2 superconducting wires, as developed originally in Cambridge [43] that include the following; a self-contained fully electric superconducting ship, DC fault current limiters, high DC current homopolar motors, cheaper superconducting MgB 2 magnets for fusion [41], SMES [41][42][43] and MRI systems. Development of liquid hydrogen indirectly cooled MgB 2 superconducting high voltage DC cables especially for computer data centres present ideal candidates for early implementation [44].…”

Section: Hydrogen As a Cryogenmentioning

confidence: 99%

Energy Management of Distributed Generation Systems

2016

3

0

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He published more than 80 papers, in national and international journals and conference proceedings, and 10 books. Dr. Mihet-Popa received the second prize paper award of the IEEE Industry Applications Society in 2005. His research interest includes modeling, simulations, control and testing of DER components in Smart Micro-Grids, electrical machines and drives, detection, and diagnosis of faults, especially for renewable conversion systems. ContentsPreface XI Section Distributed Control and Energy Management of RenewableEnergy Sources 1

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LIQHYSMES – Liquid H2 and SMES for renewable energy applications

Cited by 16 publications

References 29 publications

High Temperature Superconductors: Materials and Applications

High Temperature Superconductors: Materials and Applications

Energy Storage Technology for Decentralised Energy Management: Future Prospects

Energy Management of Distributed Generation Systems

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