Assessment of Waterfront Office Redevelopment Plan on Optimal Building Arrangements with Rooftop Photovoltaics: A Case Study for Shinagawa, Tokyo

Choi, Younghun; Kobashi, Takuro; Yamagata, Yoshiki; Murayama, Akito

doi:10.3390/en15030883

Cited by 4 publications

(2 citation statements)

References 38 publications

(35 reference statements)

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“…Under the energy consumption topic (Garcia et al, 2021), compared the greenhouse emissions associated with conventional (346,569 kg CO 2 eq/year) and solar absorption (144,452 CO 2 eq/year) cooling systems installed at a university building, suggesting that new technology should be used in universities to decrease energy consumption patterns. In this regard, digitalization, Information and Communication Technologies (ICT), and artificial intelligence (AI) can contribute to more intelligent use of energy (Parks and Wallsten, 2020;Choi et al, 2022).…”

Section: Literature Reviewmentioning

confidence: 99%

The implementation of SDG12 in and from higher education institutions: universities as laboratories for generating sustainable cities

Martínez-Acosta

Vázquez-Villegas

Mejía‐Manzano

et al. 2023

Front. Sustain. Cities

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IntroductionIt is known that the world is facing and will face significant sustainability challenges. Sustainable Development Goal 12 (SDG12), responsible consumption and production, is one of the most relevant SDGs for building Sustainable Cities. This study is based on the analysis of the implementation of SDG12 in cities, starting from universities as laboratories or first examples of sustainability.MethodsThe study was carried out through a multilevel scale approach. A systematic review of the literature (global scale) of the last 5 years (2018–2022) was conducted. An analysis of the program and the initiatives of a Higher Education Institution (Tecnologico de Monterrey) is presented (local scale). Finally, a survey was applied to Faculty at this University (micro-scale).ResultsThe systematic review indicated that the main themes or aspects addressed in SDG12 by higher education institutions were sustainable food, supply chains, community, infrastructure, technology, policies, energy consumption, the collaborative economy, smart cities, and curricula. The local scale analysis highlighted the Distrito Tec project, 37 institutional initiatives, and 26 courses directly related to SDG12. The survey showed that 8% of Faculty considered SDG12 the most important of the SDGs and stated that this goal is necessary to reduce environmental impacts. As the most significant impact that Universities can have on SDG12, 52% of the Faculty consider that Universities should become living labs in the transition toward sustainable cities, followed by 36% who think it would be better to implement operational facilities.DiscussionThe diverse contributions of the HEIs at the three scales were classified into six categories: culture, mitigation, adaptation, education, research, and outreach. The study indicates that SDG 12 has been achieved by universities in different ways, which overlaps widely with the performance of other SDGs. Results demonstrate that following a multistakeholder approach, international collaborations between HEIs can foster technology-driven multi-disciplinary research projects to consolidate sustainable cities. Building capacity to accelerate the transition of universities into urban living labs will promote climate action among the students who enroll every year.

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Section: Literature Reviewmentioning

confidence: 99%

The implementation of SDG12 in and from higher education institutions: universities as laboratories for generating sustainable cities

Martínez-Acosta

Vázquez-Villegas

Mejía‐Manzano

et al. 2023

Front. Sustain. Cities

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“…It is estimated that the windows and facades possess an energy generation potential of 2.1 GWh annually, closer to the annual power output of rooftop solar panels, highlighting the necessity to increase on-site PV generation further using facades. Younghun [129] indicated that in 2018, the photovoltaic roof had achieved economic benefits, and by 2030, it will be significantly improved, with a return on investment period of six years. However, due to the spatial constraints of roofs in large buildings, rooftop PV contributes less (2-9%) to total building demand or CO 2 reduction.…”

Section: Japan [129]mentioning

confidence: 99%

Application of Building Integrated Photovoltaic (BIPV) in Net-Zero Energy Buildings (NZEBs)

Kong,

Dong,

Poshnath

et al. 2023

Energies

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Global energy consumption has led to concerns about potential supply problems, energy consumption and growing environmental impacts. This paper comprehensively provides a detailed assessment of current studies on the subject of building integrated photovoltaic (BIPV) technology in net-zero energy buildings (NZEBs). The review is validated through various case studies, which highlight the significance of factors such as building surface area to volume ratio (A/V), window-wall ratio (WWR), glass solar heating gain coefficient (SHGC), and others in achieving the NZEBs standards. In addition, this review article draws the following conclusions: (1) NZEBs use renewable energy to achieve energy efficiency and carbon neutrality. (2) NZEBs implementation, however, has some limitations, including the negligence of indoor conditions in the analysis, household thermal comfort, and the absence of an energy supply and demand monitoring system. (3) Most researchers advise supplementing facade and window BIPV as solely roofing BIPV will not be able to meet the building’s electricity usage. (4) Combining BIPV with building integrated solar thermal (BIST), considering esthetics and geometry, enhances outcomes and helps meet NZEB criteria. (5) BIPV designs should follow standards and learn from successful cases. However, to ascertain the long-term reliability and structural integrity of BIPV systems, a comprehensive study of their potential degradation mechanisms over extended periods is imperative. The review paper aims to examine BIPV applications in-depth, underscoring its pivotal role in attaining a net-zero energy benchmark.

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Model for the implementation of strategies for the solar energy use in a healthcare network

Fondoso Ossola,

Cristeche,

Chévez

et al. 2023

e-Prime - Advances in Electrical Engineering, Electronics and E

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Assessment of Waterfront Office Redevelopment Plan on Optimal Building Arrangements with Rooftop Photovoltaics: A Case Study for Shinagawa, Tokyo

Cited by 4 publications

References 38 publications

The implementation of SDG12 in and from higher education institutions: universities as laboratories for generating sustainable cities

The implementation of SDG12 in and from higher education institutions: universities as laboratories for generating sustainable cities

Application of Building Integrated Photovoltaic (BIPV) in Net-Zero Energy Buildings (NZEBs)

Model for the implementation of strategies for the solar energy use in a healthcare network

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