Construction and operation of hydrogen energy utilization system for a zero emission building

Endo, Naruki; Shimoda, Eisuke; Goshome, Kiyotaka; Yamane, Toshihiro; Nozu, Tsuyoshi; Maeda, Tetsuhiko

doi:10.1016/j.ijhydene.2019.04.107

Cited by 55 publications

(14 citation statements)

References 30 publications

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“…[198] Furthermore, a similar material was later used in a recent study for a hydrogen energy utilization system in a zero emission building. [227] The integrated system used 520 kg of MH for 80…”

Section: Application Of Tife For Hydrogen Storagementioning

confidence: 99%

Substitutional effects in TiFe for hydrogen storage: a comprehensive review

et al. 2021

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Section: Application Of Tife For Hydrogen Storagementioning

confidence: 99%

Substitutional effects in TiFe for hydrogen storage: a comprehensive review

et al. 2021

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“…Before they can be utilized, energy resources often require conversion to other energy forms or carriers, e.g., solar photovoltaic panels to produce electricity for renewable energy resources, petroleum refineries for non-renewable energy resources, and hydrogen production from both types of energy resources. The latter example supports the idea of a hydrogen economy, in which hydrogen and electricity are the two main energy carriers (Scott 2007 ; Rosen 2017b ; Gnanapragasam and Rosen 2017 ; Moharamian et al 2019 ; Abe et al 2019 ; Endo et al 2019 ; Fonseca et al 2019 ; Chapman et al 2020 ; Al-Zareer et al 2020a ; Mehrjerdi et al 2019 ) . Energy sustainability is supported well by this combination of energy carriers since most chemical energy needs can be satisfied by hydrogen (and select hydrogen-derived fuels) and non-chemical energy needs by electricity.…”

Section: Sustainability and Energymentioning

confidence: 53%

“…A net-positive energy building over an average year generates more energy from renewable energy sources than it uses, as shown in Fig. 8 , and can support energy sustainability (Rosen 2015 ; Endo et al 2019 ; Delavar and Sahebi 2020 ; Tumminia et al 2020 ; Singh and Das 2020 ). A net-positive energy building uses energy for a variety of tasks and generates energy from various renewable energy resources, and achieves net-positive energy status through advanced design and exploitation of technologies such as advanced automation, controls, component integration, energy storage, lighting and HVAC.…”

Section: Illustrationmentioning

confidence: 99%

Energy Sustainability with a Focus on Environmental Perspectives

Rosen

2021

Earth Syst Environ

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Energy sustainability is a key consideration for anthropogenic activity and the development of societies, and more broadly, civilization. In this article, energy sustainability is described and examined, as are methods and technologies that can help enhance it. As a key component of sustainability, the significance and importance of energy sustainability becomes clear. Requirements to enhance energy sustainability are described, including low environmental and ecological impacts, sustainable energy resources and complementary energy carriers, high efficiencies, and various other factors. The latter are predominantly non-technical, and include living standards, societal acceptability and equity. The outcomes and results are anticipated to inform and educate about energy sustainability, to provide an impetus to greater energy sustainability.

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“…The entries are sorted in descending order according to the load supplied. Most of the reported pilot projects employ PV energy to power a wide range of applications such as single-family houses, 42,44,69 mobile houses, 45,46 telecom stations, 48,49 communities [58][59][60][61] and others. PV panels are much deployed as main RES because of their easier installation at roofs, facades, gardens or surrounding plots close to the target building.…”

Section: Resultsmentioning

confidence: 99%

The role of hydrogen‐based power systems in the energy transition of the residential sector

Maestre

Ortiz

Ortíz

2021

J of Chemical Tech & Biotech

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The unsustainable and continuous growth of anthropogenic emissions of greenhouse gases (GHG) has pushed governments, private companies and stakeholders to adopt measures and policies to fight against climate change. Within this framework, increasing the contribution of renewable energy sources (RES) to final consumed energy plays a key role in the planned energy transition. Regarding the residential sector in Europe, 92% of GHG emissions comes from 75% of the building stock that is over 25 years old, and highly inefficient. Thus, this sector must raise RES penetration from the current 36% to 77% by 2050 to comply with emissions targets. In this regard, the hybridization of hydrogen-based technologies and RES represents a reliable and versatile solution to facilitate decarbonization of the residential sector. This study provides an overview and analysis of standalone renewable hydrogen-based systems (RHS) focusing on the residential and buildings sector, as well as critical infrastructures like telecom stations, data servers, etc. For detailed evaluation of RHS, several pilot plants and real demonstration plants implemented worldwide are reviewed. To this end, a techno-economic assessment of relevant parameters like self-sufficiency ratio, levelized cost of energy and hydrogen roundtrip efficiency is provided. Moreover, the performance of the different configurations is evaluated by comparing the installed power of each component and their energy contribution to cover the load over a defined period of time. Challenges ahead are identified for the wider deployment of RHS in the residential and buildings sector.

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Construction and operation of hydrogen energy utilization system for a zero emission building

Cited by 55 publications

References 30 publications

Substitutional effects in TiFe for hydrogen storage: a comprehensive review

Substitutional effects in TiFe for hydrogen storage: a comprehensive review

Energy Sustainability with a Focus on Environmental Perspectives

The role of hydrogen‐based power systems in the energy transition of the residential sector

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