Smart Thermostats for a Campus Microgrid: Demand Control and Improving Air Quality

Correia, Alexandre F. M.; Ferreira, Luís Miguel; Coimbra, A. Paulo; Moura, Pedro; Almeida, Anı́bal T. de

doi:10.3390/en15041359

Cited by 11 publications

(6 citation statements)

References 23 publications

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“…The ratio between the PV system's theoretical and actual energy outputs is 88.2%. The energy sent to the grid is 6.5 MWh, whereas the energy consumed internally is 109 MWh [72]. The University of Coimbra (Portugal) has established a progressive energy system featuring PV plants, lithium-ion batteries, EVs, and advanced controllers.…”

Section: Campus Microgrid Overviewmentioning

confidence: 99%

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A Comprehensive Review of Existing and Pending University Campus Microgrids

Alhawsawi,

Salhein,

Zohdy

2024

Energies

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Over the past few decades, many universities have turned to using microgrid systems because of their dependability, security, flexibility, and less reliance on the primary grid. Microgrids on campuses face challenges in the instability of power production due to meteorological conditions, as the output of renewable sources such as solar and wind power relies entirely on the weather and determining the optimal size of microgrids. Therefore, this paper comprehensively reviews the university campuses’ microgrids. Some renewable energy sources, such as geothermal (GE), wind turbine (WT), and photovoltaic (PV), are compared in terms of installation costs, availability, weather conditions, efficiency, environmental impact, and maintenance. Furthermore, a description of microgrid systems and their components, including distributed generation (DG), energy storage system (ESS), and microgrid load, is presented. As a result, the most common optimization models for analyzing the performance of campus microgrids are discussed. Hybrid microgrid system configurations are introduced and compared to find the optimal configuration in terms of energy production and flexibility. Therefore, configuration A (Hybrid PV- grid-connected) is the most common configuration compared to the others due to its simplicity and free-charge operation.

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Section: Campus Microgrid Overviewmentioning

confidence: 99%

“…The ratio between the PV system's theoretical and actual energy outputs is 88.2%. The energy sent to the grid is 6.5 MWh, whereas the energy consumed internally is 109 MWh [72]. The University of Connecticut (USA) has developed an advanced microgrid system, incorporating various sustainable energy sources.…”

Section: Campus Microgrid Overviewmentioning

confidence: 99%

A Comprehensive Review of Existing and Pending University Campus Microgrids

Alhawsawi,

Salhein,

Zohdy

2024

Energies

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“…Smart buildings prioritize occupant well-being through features like advanced air quality monitoring and natural light optimization (Starace et al, 2022;Zivelonghi and Giuseppi, 2024;Guyot et al, 2018;Correia et al, 2022). Air quality sensors detect pollutants, triggering ventilation systems for a healthy indoor environment.…”

Section: Smart Building Systemsmentioning

confidence: 99%

Leading-Edge Technologies for Architectural Design: A Comprehensive Review

Rane,

Choudhary,

Rane

2023

IJARP

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In architecture, the incorporation of state-of-the-art technologies is crucial for advancing design methodologies and achieving groundbreaking solutions. This exhaustive review delves into a diverse array of cutting-edge technologies reshaping the architectural design landscape. The scrutinized technologies not only amplify the efficiency of design processes but also contribute to the development of sustainable, adaptable, and technologically advanced built environments. Commencing with an exploration of Artificial Intelligence (AI) in architectural design, the paper underscores how machine learning algorithms and neural networks are revolutionizing the conceptualization and optimization of architectural forms. Emphasis is placed on AI's capacity to analyze extensive datasets, predict design trends, and generate alternative designs, thereby fostering creativity and streamlining the design process. The immersive potential of Virtual Reality (VR) and Augmented Reality (AR) in architecture is thoroughly examined. The paper elucidates how these technologies are not only transforming the visualization of designs but also facilitating collaborative design processes, enabling stakeholders to experience spaces before the commencement of construction. Parametric Design and Computational Modeling are scrutinized extensively, showcasing their pivotal role in crafting intricate and optimized structures. The exploration extends to Building Information Modeling (BIM), elucidating its significance in promoting collaboration, reducing errors, and streamlining the entire building lifecycle. Moreover, Sustainable Building Materials and Technologies, Generative Design, ChatGPT, 3D/4D/5D/6D Printing, Responsive Architecture, Drones and Aerial Imaging, Digital Twin Technology are focused. Smart Building Systems, integrating IoT technologies, are explored for their role in enhancing building performance, energy efficiency, and occupant comfort.

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“…At the same time, universities face several challenges due to shrinking budgets and rising energy costs. Implementing energy efficiency programs and installing renewable energy generation technologies not only reduces primary energy consumption, costs and resources, but also greenhouse gas emissions [4][5][6].…”

Section: Introductionmentioning

confidence: 99%

Comprehensive Characterization of Energy Saving and Environmental Benefits of Campus Photovoltaic Buildings

Yang,

Cai,

Cao

et al. 2023

Energies

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The development of campus photovoltaic buildings is a promising way to solve the problem of high energy consumption in colleges and universities. However, comprehensive study on their energy saving and environmental benefits is still insufficient. In this study, a theoretical model of a photovoltaic building roof system was preliminarily built, and the main factors affecting the power generation of campus photovoltaic buildings were analyzed. Furthermore, an experimental test platform for the campus photovoltaic building system was built, and a dynamic grid-connected strategy of “spontaneous self-use, surplus electricity connected to the grid” was creatively proposed, which points out that the grid connection rate in winter and summer vacations are about 15% and over 40%, respectively, and the annual grid connection rate is 25%. The result shows that the electricity input of the campus photovoltaic building can bear nearly 30% of the school’s annual electricity supply, which reduces the comprehensive energy consumption per unit area and per capita comprehensive energy consumption of the campus by more than 20%. The economic and environmental benefits of the 130,000 square meter campus photovoltaic building in the article are 38.8 million CNY and 20.12 million CNY, respectively, and the static investment payback period is about 7 years. The results show considerable reference value to the upgrading of campus photovoltaic buildings.

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Smart Thermostats for a Campus Microgrid: Demand Control and Improving Air Quality

Cited by 11 publications

References 23 publications

A Comprehensive Review of Existing and Pending University Campus Microgrids

A Comprehensive Review of Existing and Pending University Campus Microgrids

Leading-Edge Technologies for Architectural Design: A Comprehensive Review

Comprehensive Characterization of Energy Saving and Environmental Benefits of Campus Photovoltaic Buildings

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