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dc.contributor.authorRaj, A Kanni-
dc.identifier.issn2581-8198 (Online)-
dc.description.abstractCryogenic Energy Storage (CES) improves power grid with renewable intermittent power sources. In CES, off-peak excess electricity liquefies air or natural gas. Cryogen is stored in large dewar tanks for long periods of time. Whenever electricity need is in peak, work is recovered from cryogen by a power cycle using waste heat. Many researchers focus on liquid air energy storage (LAES). But, natural gas is promising working fluid for CES. This paper reviews a natural gas-based CES system, coupled with a high grade cold storage (HGCS) unit. Cold that is stored at a low temperature has been used to raise efficiency and hike yield of liquefier. This paper models HGCS unit and compares output with experimental data. Impact of cold recycling has been analyzed for liquefier yield and storage efficiency.en_US
dc.publisherNISCAIR-CSIR, Indiaen_US
dc.rights CC Attribution-Noncommercial-No Derivative Works 2.5 Indiaen_US
dc.sourceAIR Vol.02(2) [June 2020]en_US
dc.subjectCold storageen_US
dc.subjectCryogenic energy storageen_US
dc.subjectNatural gasen_US
dc.titleCFD-subset-FVM-based MATLAB-simulation of heat transfer in high grade cold storage augmenting cryogenic energy storage system by circulating natural gas as working fluiden_US
Appears in Collections:AIR Vol.02(2) [June 2020]

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