Your search keyword '"Zero Energy Buildings"' showing total 273 results

1. Enhancing anomaly detection in electrical consumption profiles through computational intelligence

Author

Santiago Felipe Luna-Romero, Xavier Serrano-Guerrero, Mauren Abreu de Souza, and Guillermo Escrivá-Escrivà

Subjects

Building energy efficiency, Anomaly detection, Computational intelligence method, Zero energy buildings, Energy consumption patterns, Electrical energy consumption, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

The advancement of society and the raising of people's standards of living depend heavily on electricity in today's world. The ''zero energy buildings'' idea, which recommends that buildings become self-sufficient in renewable energy to prevent the emission of CO2 into the environment, is now one of the most significant initiatives connected to building energy efficiency. This article describes a computational intelligence method to detect anomalous variations in a facility's energy use and infer a potential cause of such changes. The model is built using five sets of historical power consumption data from three buildings spread across four nations (Ecuador, Spain, France, and Canada), which are categorized based on the anomaly type each piece of data represents. Through a statistical study of the confidence interval, the proposed method, first determines the consumption patterns for each day of the week in each of the building's data sets. After normalizing the day to be studied toward its ''Z'' value, it is then cataloged using a machine learning model. The proposed method is evaluated in comparison to a purely statistical method called SAEEC methodology and it is discovered that the proposed method offers a relative improvement in accuracy, false positive rate (FPR), and false negative rate (FNR) of 12.41%, 42, 36%, and 42.45%, respectively, for the detection of atypical values in electrical energy consumption.

Published

2024

2. 3D Numerical Modeling to Assess the Energy Performance of Solid–Solid Phase Change Materials in Glazing Systems.

Author

Arasteh, Hossein, Maref, Wahid, and Saber, Hamed H.

Subjects

*PHASE change materials, *FINITE volume method, *COMPUTATIONAL fluid dynamics, *PHASE transitions, *CARBON offsetting

Abstract

This research investigates the energy efficiency of a novel double-glazing system incorporating solid–solid phase change materials (SSPCMs), which offer significant advantages over traditional liquid–solid phase change materials. The primary objective of this study is to develop a 3D numerical model using the finite volume method, which will be followed by a parametric study under real climatic boundary conditions. A proposed double-glazing setup featuring a 2 mm layer of SSPCM applied on the inner glass pane within the air gap is modeled and analyzed. The simulations consider various transient temperatures and ranges of the SSPCM to evaluate the energy performance of the system under different weather conditions of Miami, FL during the coldest and hottest days of the year, both in sunny and cloudy conditions. The results demonstrate a notable improvement in energy performance compared to standard double-glazing windows (DGWs), with the most efficient SSPCM configuration exhibiting a phase transition temperature and range of 25 °C and 1 °C, respectively. This configuration achieved energy savings of 24%, 26%, and 23% during summer sunny, winter sunny, and winter cloudy days, respectively, relative to DGWs during cooling and heating degree hours. However, a 3% energy loss was observed during summer cloudy days. Overall, the findings of this study have shown the potential for energy savings by incorporating SSPCM with suitable thermophysical properties into double-glazing systems. [ABSTRACT FROM AUTHOR]

Published

2024

3. Recent improvements to heating, ventilation, and cooling technologies for buildings based on renewable energy to achieve zero-energy buildings: A systematic review

Author

Baseem A. Aljashaami, Bashar M. Ali, Sajjad A. Salih, Naseer T. Alwan, Milia H. Majeed, Obed M. Ali, Omar R. Alomar, Vladimir I. Velkin, and Sergey E. Shcheklein

Subjects

Zero energy buildings, Energy efficiency, HVAC, Renewable energy, Hybrid systems, Technology

Abstract

Due to global climate change and energy market turmoil, the world is seriously pushing to switch to renewable and diversifying energy sources. The building sector consumes an amount of energy, accounting for approximately 40 % of global energy. Therefore, the concept of zero-energy buildings has become more realistic than before. This study reveals the latest developments in zero-energy buildings through a comprehensive literature review of the past ten years. Emphasis has been placed on buildings' heating, ventilation, and cooling systems, as they constitute the most important part of the energy demand. Also, the role of negative energy resulting from an improved building envelope through the design of a building compatible with the surrounding environment, thermal insulation materials, phase change materials, vegetation cover, etc. A review was also made of the most significant renewable energy technologies, which include solar energy installations, wind turbines, and geothermal heat exchangers. The study showed that three main axes must be achieved to reach an energy-free building: Reducing energy waste through the energy-conserving building envelope and improving HVAC systems. Raising the efficiency of the performance of renewable energy facilities by using hybrid systems with the ability and flexibility to respond to changing energy demand. These three axes are an integrated approach to achieving ZEBs; none can be neglected. This study provides important references for researchers, institutions, and decision-makers to unify efforts to achieve ZEBs. It also aims to attract attention and focus research by raising questions and identifying gaps that future research efforts can address.

Published

2024

4. A Framework of Decision Support System from BIM to Digital Twin Aiming Zero Energy Buildings

Author

Aydin, Mehmet Akif, Oral, Gul Koclar, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Lu, Xinzheng, Series Editor, Kang, Thomas, editor, and Lee, Youngjin, editor

Published

2024

5. Machine learning applications for photovoltaic system optimization in zero green energy buildings

Author

Wei Liu, Yedan Shen, Pasura Aungkulanon, Mohammad Ghalandari, Binh Nguyen Le, Aníbal Alviz-Meza, and Yulineth Cárdenas-Escrocia

Subjects

Zero energy buildings, Machine learning, Optimization, Photovoltaic systems, Solar panel, Nano-composite material, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

In this paper, the energy supply of a zero-energy building with 220 square meters is considered using optimized nanocomposite solar panels with respect to maximum efficiency. An optimized hybrid machine learning method plays a key role in presenting solar panel modeling with over 0.99% accuracy. Predicting the properties of the nanomaterial solar cell in four different seasons is performed by efficient support vector machines (SVM), and k-nearest neighbors (KNN) machine learning algorithms. In addition, the KNN algorithm is optimized by the Particle Swarm Optimization (PSO) method to improve the capabilities of KNN and reveal the best performance criteria for the photovoltaic modeling characteristics. The parameters of the nanocomposite cells are optimized using the proposed novel Multidisciplinary Optimization Method (MDO) to increase the efficiency of the solar panel by up to 170%. Optimization of solar cell performance with nanocomposite material under energy consumption constraints is carried out to propose the best construction of cells with 3 layers. The presented approach as a solution and indicator for the next generation of commercial and residential buildings can increase the potential values of solar cells to at least 70%.

Published

2023

6. 3D Numerical Modeling to Assess the Energy Performance of Solid–Solid Phase Change Materials in Glazing Systems

Author

Hossein Arasteh, Wahid Maref, and Hamed H. Saber

Subjects

carbon neutrality, building energy, solid–solid phase change material, glazing system, zero energy buildings, computational fluid dynamics, Technology

Abstract

This research investigates the energy efficiency of a novel double-glazing system incorporating solid–solid phase change materials (SSPCMs), which offer significant advantages over traditional liquid–solid phase change materials. The primary objective of this study is to develop a 3D numerical model using the finite volume method, which will be followed by a parametric study under real climatic boundary conditions. A proposed double-glazing setup featuring a 2 mm layer of SSPCM applied on the inner glass pane within the air gap is modeled and analyzed. The simulations consider various transient temperatures and ranges of the SSPCM to evaluate the energy performance of the system under different weather conditions of Miami, FL during the coldest and hottest days of the year, both in sunny and cloudy conditions. The results demonstrate a notable improvement in energy performance compared to standard double-glazing windows (DGWs), with the most efficient SSPCM configuration exhibiting a phase transition temperature and range of 25 °C and 1 °C, respectively. This configuration achieved energy savings of 24%, 26%, and 23% during summer sunny, winter sunny, and winter cloudy days, respectively, relative to DGWs during cooling and heating degree hours. However, a 3% energy loss was observed during summer cloudy days. Overall, the findings of this study have shown the potential for energy savings by incorporating SSPCM with suitable thermophysical properties into double-glazing systems.

Published

2024

7. Energy Audit in Buildings for Sustainable Economic Development

Author

Kalair, Ali Raza, Seyedmahmoudian, Mehdi, Abas, Naeem, Saleem, Muhammad Shoaib, Stojcevski, Alex, Mekhilef, Saad, Koh, Kek, Tsounis, Nicholas, editor, and Vlachvei, Aspasia, editor

Published

2023

8. Urban energy planning towards achieving an economically and environmentally optimized energy flow by 2050 based on different scenarios (a case study)

Author

Jahangir, Mohammad Hossein, Mokhtari, Reza, Salmanpour, Fatemeh, and Yousefi, Hossein

Published

2024

9. Economic Evaluation of Small Public Office Buildings with Class 1 of Zero Energy Building (ZEB) in Korea by Reflecting Life Cycle Assessment (LCA).

Author

Lee, Duhwan, Kim, Jaemoon, and Kim, Young Il

Subjects

PRODUCT life cycle assessment, NET present value, ENVIRONMENTAL economics

Abstract

This study summarizes the technology level and economic feasibility of two small 500 m2 public office buildings that achieved a first-class Zero Energy Buildings (ZEB) certification for the first time in Korea. In addition, a Life Cycle Assessment (LCA) reflecting the ZEB performance in the operation stage was analyzed, and the LCA factors considering the characteristics of small buildings were reviewed. Moreover, an economic analysis was performed through a Net Present Value (NPV) by reflecting the ZEB and LCA, and the results showed little economic feasibility. However, adding the environmental costs calculated through the LCA to the existing energy-saving costs could offset an additional 11.6–11.7%. Therefore, including the environmental impact and cost through these LCA evaluation techniques could be a positive step toward increasing the effectiveness of ZEB applications. This study is significant in that it conducted a comprehensive analysis through ZEB and LCA in terms of carbon reduction for small buildings that achieved a first-class ZEB certification, but it is limited to only two cases. [ABSTRACT FROM AUTHOR]

Published

2023

10. A SYSTEMATIC REVIEW OF DIFFERENT TYPES OF ZERO ENERGY BUILDINGS RESEARCH OVER THE PAST 45 YEARS.

Author

Sabour, M. R., Abdolmaleki, A. R., and Jafari, M. A.

Subjects

ENERGY consumption of buildings, BIBLIOMETRICS, ENERGY consumption, DATABASES, CONSUMPTION (Economics), SCIENTIFIC knowledge

Abstract

Numerous environmental issues have been addressed as a consequence of rapidly increasing global energy consumption. Building energy consumption has risen considerably in the last few decades. In recent years, the zero energy building (ZEB) concept has attained worldwide attention and is now commonly identified as the future criteria for building design. However, there is a lack of uniform definition in this field. This study combines bibliometric and visual analysis of Scopus database publications from 1977 to 2022 to investigate ZEB-related studies. Five topical clusters formed as a result of evaluating the co-occurrence network of the keywords. Finally, the most popular research trends were determined by investigating the overlay network. The scientific knowledge concerning zero energy buildings has been mapped by employing the results of this paper. In addition, they have been utilized to highlight future opportunities and gaps and illustrate the connections between various subject areas. [ABSTRACT FROM AUTHOR]

Published

2023

11. Roadmap to a Sustainable Energy System: Is Uncertainty a Major Barrier to Investments for Building Energy Retrofit Projects in Wide City Compartments?

Author

Gabrielli, Laura, Ruggeri, Aurora Greta, and Scarpa, Massimiliano

Subjects

*RETROFITTING of buildings, *MONTE Carlo method, *ROAD maps, *EPISTEMIC uncertainty, *SENSITIVITY analysis

Abstract

Along the roadmap to a Sustainable Real Estate-Scape, energy retrofit campaigns on wide city compartments represent a pivotal task, where the importance of the collaboration between the public and private sectors is crucial. Energy retrofit programs on building assets are subject to multiple uncertainty factors (e.g., climate, energy-economy forecasts, etc.) that act as a primary barrier to investment in this field. This paper aims to discuss risk management techniques to understand better how to deal with this kind of uncertainty. The research specifically addresses the techniques of sensitivity analysis and Monte Carlo simulation, focusing first on the phase of variables selection and their probability definition, including climatic, environmental, energy, economic, financial, and stochastic parameters. In this article, it is suggested to include correlation coefficients in the input variables of risk analysis, preferring the two-dimension Monte Carlo simulation to its simple version, since the results are more reliable when separating aleatory from epistemic uncertainty; thus, the results are more reliable. Moreover, it is seen how a sensitivity analysis based on percentile variations of the inputs provides a more accurate representation of risk if compared to the most common sensitivity analysis based on percentage deviations of the inputs. Conducting a sensitivity analysis using percentile variations gives realistic and reliable results, reflecting the tailored definition of uncertainty around the inputs on the basis of specific market analyses or historical series. [ABSTRACT FROM AUTHOR]

Published

2023

12. Renewable Energy Integration and Zero Energy Buildings

Author

Heperkan, Hasan Alpay, Önal, Büşra Selenay, Uyar, Tanay Sıdkı, Uyar, Tanay Sıdkı, editor, and Javani, Nader, editor

Published

2022

13. Assessment of key financial supports for promoting zero energy office buildings investment in Thailand using sensitivity analysis

Author

Daranee Jareemit, Anake Suwanchaisakul, and Bundit Limmeechokchai

Subjects

Zero energy buildings, Sensitivity analysis, Net present value, Office building, Energy-efficiency, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Thailand has pledged to be carbon neutral by 2050 at the UN Climate Change Conference (COP26). Promoting all-new buildings to be net-zero energy consumption within 2030 is a strategy to achieve the goal. The previous works have revealed that policymakers and related stakeholders’ supportive strategies could significantly contribute to promoting the zero-energy buildings (ZEB) investment. Moreover, another big challenge in improving high-energy-efficient buildings is the high initial cost and uncertainties of the future costs. As far as we know, no studies have investigated an effect of such a change in economic and relevant costs on the financial benefits of the ZEB project in Thailand. Such parameters are a significant barrier to decision-making on ZEB investment. Consequently, the guidance for affordable financial feasibility and supportive measures could significantly promote ZEB projects. This study used sensitivity analysis to assess the variations of future costs, including initial cost, energy price, maintenance & operation cost, interest rate, and discount rate, influencing the project’s NPVs and the global costs of three representative office buildings. The analyses showed that the total cost was strongly sensitive to the investment cost, with a maximum reduction of 15.76% when the investment cost was reduced by 20%. The NPV was significantly influenced by energy price, with the variations ranging from 2.83% to 15.12%. ZEB development in large buildings provided more financial profitability than in small buildings. Finally, the key effective financial parameters and the key persons responsible for supporting financial measures were proposed to promote ZEB project investment in Thailand. The increase in energy prices and the decrease in initial cost, especially the cost of the air-conditioning systems, will increase investment returns. However, such increments in energy price also affect small and low-income enterprises. For future implementations of ZEB, policymakers should investigate suitable measures and financial incentives.

Published

2022

14. Moving toward Net Zero Carbon Buildings to Face Global Warming: A Narrative Review.

Author

Tirelli, Davide and Besana, Daniela

Subjects

GLOBAL warming, PARIS Agreement (2016), GEOTHERMAL resources, CARBON emissions, CIRCULAR economy, CARBON offsetting, PASSIVHAUS

Abstract

The increase in global surface temperatures will surpass the 2 °C target set by the Paris Agreement unless carbon emissions are lowered to zero by 2050. To date, the building sector is responsible for 38% of all carbon emissions, thus one of the main targets is represented by the development of building strategies that can facilitate the transition toward carbon-neutral buildings. The main strategies are today represented by nearly zero energy buildings (nZEBs), zero energy buildings (ZEBs)/net zero energy buildings (NZEBs) and net zero carbon buildings (NZCBs). Particularly, NZCBs completely target zero operational and embodied carbon during their life cycles, fulfilling the leadership role in the decarbonization of the construction sector. Moreover, adopting the European Standard EN 15978:2011, carbon emissions can be precisely classified to enhance strategies aimed at reducing them. Commercial viability remains a fundamental economic driver, but the higher initial capital costs hinder the NZCBs. In addition, legislative, socio-cultural, technological, professional and geographical barriers hold back its diffusion. NZCBs can be met by a four-steps program: embodied carbon reduction, operational carbon reduction, increase in renewable energy supply and offset and carbon storage. Circular economy principles are strictly connected to design for disassembly and for adaptability to reduce embodied carbon, while passive design and solar and geothermal energy production can satisfy the renewable energy demand of the building. The aim of this narrative review is to determine and describe which is the current state of the art for NZCB definition, the drivers and barriers toward its application in a broader context and which strategies are eligible to meet the ambitious goal of zero operational and zero embodied carbon emissions. [ABSTRACT FROM AUTHOR]

Published

2023

15. Identification and Prioritizing Suitable Cities to Construct Zero Energy Buildings Using MADM Techniques (Case Study: Iran)

Author

Aliyeh Kazemi, Parichehr Nouri, and Sara Aryaee

Subjects

zero energy buildings, iran, fuzzy delphi method, multi-attribute decision making methods, City planning, HT165.5-169.9, Urban renewal. Urban redevelopment, HT170-178

Abstract

Increasing demand for energy due to population growth and global warming has led to numerous environmental issues such as deforestation, destruction of the ozone layer, drought, storms, and floods. These have encouraged researchers to seek new ways to use clean, renewable energies. The construction of Zero Energy buildings in Iran cities can be a significant step forward in economic development and pollution reduction in metropolitan areas. This study aims to identify and prioritize suitable cities in Iran to build Zero Energy buildings. For this purpose, the fuzzy Delphi and multi-attribute decision-making (MADM) methods have been used. The cities that are suitable for the construction of zero-energy buildings were selected through interviews with individuals who are experts in the fields of architecture, urban planning, and energy management and who are familiar with the construction of Zero Energy buildings, as well as considering the results of previous research and the characteristics of different cities. Then, with the fuzzy Delphi method, the necessary indicators for the priority of the selected cities were determined, and their weight was determined. After that, the cities were prioritized using MADM methods. The results showed that Yasuj, Shiraz, Tabriz, and Arak are suitable cities to build Zero Energy buildings in Iran.

Published

2022

16. Net-Zero and Positive Energy Communities : Best Practice Guidance Based on the ZERO-PLUS Project Experience

Author

Shabtai Isaac, Isaac Meir, Gloria Pignatta, Shabtai Isaac, Isaac Meir, and Gloria Pignatta

Subjects

Zero energy buildings, Renewable energy sources

Abstract

This book presents a methodology for the design, construction, monitoring, optimization, and post-occupancy evaluation of net-zero and positive-energy communities based on the experiences gained in the EU Horizon 2020 ZERO-PLUS project. It describes the steps, tools, and methods developed during the project, providing practical information for the energy and construction sector that will be of interest to students, engineers, architects, developers, and professionals working around high performance architecture and sustainable communities.Through the ZERO-PLUS project, a consortium of 32 partners from eight countries, including academic institutions, technology providers, architects, and construction companies, designed four communities covering completely different geo-climatic regions, construction practices, and cultural backgrounds in Cyprus, Italy, France, and the UK. The communities were designed, optimized, constructed, monitored, handed over to tenants, post-occupancy evaluated, and troubleshooted through a system of continuous collaboration and data acquisition. This book presents these case studies and shows how the project targets of reducing electricity consumption below 20 kWh/m2/y, increasing electricity production from Renewable Energy Systems to over 50 kWh/m2/y, and at cheaper costs when compared to current zero-energy buildings were reached and surpassed. These cases demonstrate that a holistic and interactive approach to design and construction can bring communities a high standard of sustainability.The key features of the book include: Practical guidance drawn from the interdisciplinary, international, and remote cooperation between experts from academia and industry across the construction sector A survey of the state-of-the-art on net-zero and positive-energy communities, including the experience and the lessons learned from previous projects and from the ZERO-PLUS project Descriptions of novel emerging renewable energy technologies, integrated into real case study communities to achieve the energy generation target of the communities A comprehensive set of approaches, tools, guidelines, best practices, challenges, and lessons learned from the five-year ZERO-PLUS project and the completion of four residential case studies to inform the reader of how to achieve affordable net-zero energy communities Four typologies of residential communities located in different climatic conditions are presented, touching on the critical aspects of the design, construction, monitoring, and occupancy phase A discussion of future trends for developing communities that are more liveable, accessible, and sustainable and which can comply with new energy policies in a way that is affordable for the owners and residents.

Published

2023

17. Zero energy potential of PV direct-driven air conditioners coupled with phase change materials and load flexibility.

Author

Li, Sihui, Peng, Jinqing, Li, Houpei, Zou, Bin, Song, Jiaming, Ma, Tao, and Ji, Jie

Subjects

*PHASE change materials, *POTENTIAL energy, *WINTER, *UNIVERSAL design, *OFFICES

Abstract

Without any assistance, the energy matching between air conditioner load demand and PV generation of PV direct driven Air Conditioners (PVACs) is inflexible. Phase Change Materials (PCMs) and building load flexibility can improve the real-time Zero Energy Probability (ZEP). In this paper, a coupling system consisting of PVACs, PCMs, and load flexibility was proposed for an office building. Sensitive analysis were conducted for different PCMs coupled with PVACs and load flexibility to improve the real-time ZEP with considering the PV capacity Factors (PVF), PCM type, and PCM thickness. According to the influence on the ZEP, the key parameters of the coupling system were ranked as follows: PVF > PCM melting temperature > PCM thickness. PCMs can reduce the PVF by 26.67% and assist the system achieving a 90% real-time ZEP in summer. The recommended PVF for the Hot-summer and Warm-winter and the Hot-summer and Cold-winter zone are 1.3 and 1.0, respectively, while the optimized PCM melting temperature are 27 °C and 26 °C, respectively. In summary, a complete evaluation method, a universal design route and different optimization schemes for PVACs coupled with PCMs and load flexibility were proposed in this paper, and it is conducive to the improvement of the real-time ZEP. [ABSTRACT FROM AUTHOR]

Published

2022

18. Simultaneity in Renewable Building Energy Supply—A Case Study on a Lecturing and Exhibition Building on a University Campus Located in the Cfb Climate Zone.

Author

Gehlert, Gunther, Wiegand, Marlies, Lymar, Mariya, and Huusmann, Stefan

Abstract

A major issue in the renewable energy supply of buildings is to establish a simultaneity of the fluctuating renewable energy generation and the energy consumption in buildings. This work provides a new case for a better understanding of how to establish this simultaneity. Future solutions are being explored in practice on the campus of the FH Westküste University of Applied Sciences in the Lecturing and Exhibition Building (LEB). The motivation was to design and operate a case building for research in energy science for teaching the bachelor's program Green Building Systems as well as for demonstration purposes for the general public. With a floor space of 207 m, the LEB is supplied with renewable energy from the adjacent energy park consisting of a 10 kW wind turbine and photovoltaic modules with 10 kWp. The heat and cold generation system consists of two reversible heat pumps: one is an air–water heat pump with approx. 7 kW heating and 6 kW cooling power, and the second is a brine–water heat pump with approx. 8 kW heating power and a depth of the two boreholes of 80 m. To match the energy generation and the energy consumption, different kinds of storage units, i.e., batteries with 3 × 8 kWh and storage tanks with 1000 L heat storage and 600 L cold storage, were installed as well as a smart automation system with a database. This paper evaluates measurement data from 2021. It is demonstrated that a fully renewable energy supply of the building is possible for most of the time from spring to autumn. In winter, an additional long-term energy storage, e.g., hydrogen, is necessary for certain days. [ABSTRACT FROM AUTHOR]

Published

2022

19. Bibliometric analysis of zero energy building research, challenges and solutions.

Author

Souley Agbodjan, Yawovi, Wang, Jiaqiang, Cui, Yanping, Liu, Zhiqiang, and Luo, Zhengyi

Subjects

*BIBLIOMETRICS, *PRODUCT life cycle assessment, *ENERGY development, *ENERGY consumption

Abstract

• Bibliometrics overview of ZEB publications. • Draw of the collaboration networks from ZEB research publications. • Brought out thematic trend of the development ZEB over the time. • Discussions of the main challenges and solutions for ZEB studies. Zero Energy Building (ZEB) is gaining more attention as a solution to significantly mitigate the environment concerns. However, a bibliometric analysis of the topic, a very useful method to analyze the database of published publications and reviews, is lacking. Especially, to provide when and how this concept has been brought out, insights into the state-of-art technology, the findings of the collaboration networks and the challenges of ZEB. To address this gap, in this paper, ZEB studies have been reviewed using multiple perspectives and analytical tools, such as VOSviewer and Biblioshiny to analyze the collaboration networks and the thematic trends of ZEB publications. The original data was retrieved in Scopus, a total of 1051 documents including research articles and reviews published from 1976 to 2020. The analysis of the number of publications over the years shows that the development of Zero energy building research has gone through three stages: a slow development period from 1076 to 1999, followed by a development from 2000 to 2010 and finally a rapid development from 2011 to 2020. The study also reveals different rankings, including the most widely collaborated scholars, the most cited scholars, the most published countries, etc. Therein, the United State, United Kingdom and China have the most research on ZEB. Based on the analysis of co-occurrence network and evolution of thematic keywords, it is found that energy efficiency and life cycle assessment (LCA) are the main challenges for the achievement of ZEB target. Finally, these challenges have been discussed and solutions provided. [ABSTRACT FROM AUTHOR]

Published

2022

20. Success Factors and Barriers for Facility Management in Keeping Nearly-Zero-Energy Non-Residential Buildings Energy-Efficient over Time

Author

Lane, Anna-Lena, Cehlin, Mathias, Thollander, Patrik, Lane, Anna-Lena, Cehlin, Mathias, and Thollander, Patrik

Abstract

Energy efficiency is a cornerstone of climate change mitigation. For buildings, facility management is an essential part of achieving efficient energy use while keeping tenants satisfied. This interview study explores success factors and barriers for facility management in maintaining energy efficiency over time in four approximately 10-year-old non-residential premises built as so-called nearly zero-energy buildings (nZEB) in Sweden. The study highlights the importance of functional digital tools, benchmarks, and building professionals’ involvement in ensuring energy efficiency. It also emphasizes the need for involvement communication and strategies to engage facility management in energy efficiency efforts. The study suggests that in-house and public policies can play a crucial role in sustaining high ambitions for energy efficiency. Access to professional support that is self-evident to use is identified as a critical success factor. Additionally, the research presents an analytic model that can be used in future studies to assess facility management organizations’ potential for maintaining energy performance in buildings over time., This study was founded by the Swedish Energy Agency within the research program E2B2 (project number 50407-1). The work was carried out under the auspices of the PhD school Reesbe, which is financed by the Swedish Knowledge Foundation (KK-stiftelsen, project number 20150133).

Published

2024

21. Very high temperature BTES : A potential for operationally cost-free and emission-free heating

Author

Ekmekci, Ece, Aydin, Murat, Ozturk, Z. Fatih, Sisman, Altug, Ekmekci, Ece, Aydin, Murat, Ozturk, Z. Fatih, and Sisman, Altug

Abstract

In cold climates, the heating load is much higher than the cooling load and borehole thermal energy storage (BTES) systems offer an opportunity for high -efficient heating. Heat energy from different sources is stored in the ground to use in wintertime. Higher storage temperatures lower the operating cost of heating and the size of the BTES field. BTES systems, up to 90°C, are studied in the literature. In this study, we consider the charge temperatures beyond 100°C to analyze the possibility of free -heating for Nordic countries. The system is called here very high -temperature BTES (VHT-BTES). A residence field of 25 houses, 125m2 each, is chosen as a mid -scale target and concentrated solar collectors (CSC) are used to charge VHT-BTES up to 140°C. A double -ring layout of ten boreholes is optimized to minimize the heat pump consumption. Free -heating and heat pump modes are activated for high and low borehole temperatures, respectively. The actual meteorological data for Uppsala/Sweden is used. The gradually increasing very high seasonal coefficient of performance values (SCOP), 8-23, are achieved using free -heating and heat pump modes together for the first four years. From the fifth year, all of the heating demand is basically met by the stored energy (free -heating). The results show that VHT-BTES provides practically operationally cost-free and emission -free heating even for a Nordic country. The return of investment is calculated as ten to fourteen years, depending on the cost of the additional land for CSC.

Published

2024

22. Development of Hybrid System for Air-Conditioning of Almost Zero Energy Buildings

Author

Šunje, Edin, Pašić, Sead, Isić, Safet, Nezirić, Emir, Džiho, Edin, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, and Karabegović, Isak, editor

Published

2020

23. Smart Zero-energy Buildings and Communities for Smart Grids

Author

Nikos Kampelis, Denia Kolokotsa, Nikos Kampelis, and Denia Kolokotsa

Subjects

Smart power grids, Architecture and energy conservation, Zero energy buildings

Abstract

Smart zero-energy buildings and communities have a major role to play in the evolution of the electric grid towards alignment with carbon neutrality policies. The goal to reduce greenhouse gas emissions in the built environment can be pursued through a holistic approach, including the drastic reduction of buildings'energy consumption.The state-of-the-art in this field relates, on the one hand, to design methodologies and innovative technologies which aim to minimize the energy demand at the building level. On the other hand, the development of information and communication technologies, along with the integration of renewable energy and storage, provide the basis for zero and positive energy buildings and communities that can produce, store, manage and exchange energy at a local level.This book provides a structured and detailed insight of the state-of-the-art in this context based on the analysis of real case studies and applications.

Published

2022

24. Contribution of nearly-zero energy buildings standards enforcement to achieve carbon neutral in urban area by 2060

Author

Shi-Cong Zhang, Xin-Yan Yang, Wei Xu, and Yi-Jun Fu

Subjects

Ultra-low energy buildings, Nearly-zero energy buildings, Zero energy buildings, Building energy consumption, Building carbon emission, Meteorology. Climatology, QC851-999, Social sciences (General), H1-99

Abstract

Nearly-zero energy buildings (NZEB) would effectively improve building energy efficiency and promote building electrification. By using a carbon emission model integrated into a bottom-up mid-to-long term energy consumption model, this study analyzes the contribution of NZEB standards to carbon emission targets in the urban area of China by 2060. Three scenarios are set, namely BAU, steady development (S1), and high-speed development (S2). For BAU, the total carbon emissions will reach a peak of 1.94 Gt CO2 by 2040. In S1 scenario, total building carbon emissions will reach the peak of 1.72 Gt CO2 by 2030. In S2 scenario, the carbon emissions will reach a peak by 2025 with 1.64 Gt CO2. Under S1 scenario, which features consistency with NZEB market development and periodic improvement of building energy-efficiency standards, the carbon emission peak in 2030 will be accomplished. To achieve carbon neutrality by 2060, the upgrading of building energy standards to NZEB will contribute 50.1%, while zero-carbon electricity contribution is 49.9%. It is concluded that 2025, 2030, and 2035 could be set as mandatory enforcement years for ultra-low energy buildings, NZEB and zero energy building (ZEB), respectively.

Published

2021

25. Economic Evaluation of Small Public Office Buildings with Class 1 of Zero Energy Building (ZEB) in Korea by Reflecting Life Cycle Assessment (LCA)

Author

Duhwan Lee, Jaemoon Kim, and Young Il Kim

Subjects

small office buildings, zero energy buildings, ZEB certification, life cycle assessment, Net Present Value, Building construction, TH1-9745

Abstract

This study summarizes the technology level and economic feasibility of two small 500 m2 public office buildings that achieved a first-class Zero Energy Buildings (ZEB) certification for the first time in Korea. In addition, a Life Cycle Assessment (LCA) reflecting the ZEB performance in the operation stage was analyzed, and the LCA factors considering the characteristics of small buildings were reviewed. Moreover, an economic analysis was performed through a Net Present Value (NPV) by reflecting the ZEB and LCA, and the results showed little economic feasibility. However, adding the environmental costs calculated through the LCA to the existing energy-saving costs could offset an additional 11.6–11.7%. Therefore, including the environmental impact and cost through these LCA evaluation techniques could be a positive step toward increasing the effectiveness of ZEB applications. This study is significant in that it conducted a comprehensive analysis through ZEB and LCA in terms of carbon reduction for small buildings that achieved a first-class ZEB certification, but it is limited to only two cases.

Published

2023

26. Bio‐Based Solar Energy Harvesting for Onsite Mobile Optical Temperature Sensing in Smart Cities.

Author

Correia, Sandra F.H., Bastos, Ana R.N., Martins, Margarida, Macário, Inês P.E., Veloso, Telma, Pereira, Joana L., Coutinho, João A.P., Ventura, Sónia P.M., André, Paulo S., and Ferreira, Rute A.S.

Subjects

*SMART cities, *ENERGY harvesting, *SOLAR energy, *SOLAR concentrators, *GREEN fluorescent protein, *INTERNET of things, *BIOMASS liquefaction

Abstract

The Internet of Things (IoT) fosters the development of smart city systems for sustainable living and increases comfort for people. One of the current challenges for sustainable buildings is the optimization of energy management. Temperature monitoring in buildings is of prime importance, as heating account for a great part of the total energy consumption. Here, a solar optical temperature sensor is presented with a thermal sensitivity of up to 1.23% °C−1 based on sustainable aqueous solutions of enhanced green fluorescent protein and C‐phycocyanin from biological feedstocks. These photonic sensors are presented under the configuration of luminescent solar concentrators widely proposed as a solution to integrate energy‐generating devices in buildings, as windows or façades. The developed mobile sensor is inserted in IoT context through the development of a self‐powered system able to measure, record, and send data to a user‐friendly website. [ABSTRACT FROM AUTHOR]

Published

2022

27. The Unsustainable Direction of Green Building Codes: A Critical Look at the Future of Green Architecture.

Author

Capeluto, Isaac Guedi

Subjects

SUSTAINABLE buildings, SUSTAINABLE design, URBAN planning, CARBON emissions, LAND use, SOLAR technology, SUSTAINABLE architecture, BUILDING performance

Abstract

Buildings are a major contributor to global energy consumption and energy-related carbon dioxide emissions. In light of the climate crisis, changes in the way we design, construct and use buildings are needed to reduce their environmental impact. Green Building Codes (GBCs) and rating systems have been developed around the world as a basis for green building practices. However, several studies raised doubts about the actual performance of certified buildings. Moreover, they use a per unit area approach to assess the use of resources rather than per capita, penalizing small buildings or those with high occupancy, ignoring the concepts of equity and shared common effort which are central to sustainable design. In this paper we propose adjustments to GBCs to encourage new ways of designing and evaluating green buildings. We introduce the Occupancy Correction Factor (OCF) which prioritizes smaller and more densely occupied buildings reducing land use, total operational energy consumption and embodied energy. Results show changes in their energy ratings of one to three levels both up and down, compared to their original ratings. In addition, we propose the prioritization of high-efficiency Low-Energy and Nearly Zero-Energy buildings over Net Zero Energy buildings, encouraging innovative urban design to enhance solar access and electricity production potential on-site or nearby. [ABSTRACT FROM AUTHOR]

Published

2022

28. Roadmap to a Sustainable Energy System: Is Uncertainty a Major Barrier to Investments for Building Energy Retrofit Projects in Wide City Compartments?

Author

Laura Gabrielli, Aurora Greta Ruggeri, and Massimiliano Scarpa

Subjects

energy efficiency, zero energy buildings, low-emission buildings, smart buildings, sustainable city, climate mitigation, Technology

Abstract

Along the roadmap to a Sustainable Real Estate-Scape, energy retrofit campaigns on wide city compartments represent a pivotal task, where the importance of the collaboration between the public and private sectors is crucial. Energy retrofit programs on building assets are subject to multiple uncertainty factors (e.g., climate, energy-economy forecasts, etc.) that act as a primary barrier to investment in this field. This paper aims to discuss risk management techniques to understand better how to deal with this kind of uncertainty. The research specifically addresses the techniques of sensitivity analysis and Monte Carlo simulation, focusing first on the phase of variables selection and their probability definition, including climatic, environmental, energy, economic, financial, and stochastic parameters. In this article, it is suggested to include correlation coefficients in the input variables of risk analysis, preferring the two-dimension Monte Carlo simulation to its simple version, since the results are more reliable when separating aleatory from epistemic uncertainty; thus, the results are more reliable. Moreover, it is seen how a sensitivity analysis based on percentile variations of the inputs provides a more accurate representation of risk if compared to the most common sensitivity analysis based on percentage deviations of the inputs. Conducting a sensitivity analysis using percentile variations gives realistic and reliable results, reflecting the tailored definition of uncertainty around the inputs on the basis of specific market analyses or historical series.

Published

2023

29. Moving toward Net Zero Carbon Buildings to Face Global Warming: A Narrative Review

Author

Davide Tirelli and Daniela Besana

Subjects

net zero carbon buildings, carbon-neutral buildings, zero energy buildings, embodied carbon, climate change, global warming, Building construction, TH1-9745

Abstract

The increase in global surface temperatures will surpass the 2 °C target set by the Paris Agreement unless carbon emissions are lowered to zero by 2050. To date, the building sector is responsible for 38% of all carbon emissions, thus one of the main targets is represented by the development of building strategies that can facilitate the transition toward carbon-neutral buildings. The main strategies are today represented by nearly zero energy buildings (nZEBs), zero energy buildings (ZEBs)/net zero energy buildings (NZEBs) and net zero carbon buildings (NZCBs). Particularly, NZCBs completely target zero operational and embodied carbon during their life cycles, fulfilling the leadership role in the decarbonization of the construction sector. Moreover, adopting the European Standard EN 15978:2011, carbon emissions can be precisely classified to enhance strategies aimed at reducing them. Commercial viability remains a fundamental economic driver, but the higher initial capital costs hinder the NZCBs. In addition, legislative, socio-cultural, technological, professional and geographical barriers hold back its diffusion. NZCBs can be met by a four-steps program: embodied carbon reduction, operational carbon reduction, increase in renewable energy supply and offset and carbon storage. Circular economy principles are strictly connected to design for disassembly and for adaptability to reduce embodied carbon, while passive design and solar and geothermal energy production can satisfy the renewable energy demand of the building. The aim of this narrative review is to determine and describe which is the current state of the art for NZCB definition, the drivers and barriers toward its application in a broader context and which strategies are eligible to meet the ambitious goal of zero operational and zero embodied carbon emissions.

Published

2023

30. Stochastic Optimal Device Sizing Model for Zero Energy Buildings: A Parallel Computing Solution.

Author

Mehrtash, Mahdi, Mozafari, Ghazaleh, Hua, Kaixun, and Cao, Yankai

Subjects

*PARALLEL programming, *EMISSIONS (Air pollution), *NONLINEAR programming, *SCHUR complement, *GLOBAL warming, *BUILDING-integrated photovoltaic systems, *BATTERY storage plants

Abstract

Byconsuming35% of the final global energy, buildings are among major contributors to greenhouse gas emissions and global warming. If the economic justification challenge is addressed, zero energy buildings (ZEB), which are defined as buildings that generate as much renewable-based energy as they consume annually, can be a promising solution for energy efficiency improvement in the building sector. In this article, we propose a stochastic ZEB device sizing model considering uncertain parameters (i.e., building's electrical and thermal demands, solar irradiation, and outdoor temperature) and their correlation. The proposed model finds the optimal size of the thermal and electrical devices considering their nonlinear behaviors and temperature-dependent dynamics. Furthermore, two parallel computing-based solution algorithms (i.e., parallelism in the algebraic level using Schur complement decomposition and parallelism in the problem (scenario) level by progressive hedging) are proposed to solve the stochastic model. Using the real historical data, numerical studies on the Woodward library building, located on the University of British Columbia campus, illustrate the efficacy of the solution algorithms to handle large-scale nonlinear programming models with more than 32.8 million variables, which is the largest one reported in the literature so far. [ABSTRACT FROM AUTHOR]

Published

2022

31. Designing Zero-Energy Buildings Using Advanced Fuzzy Cognitive Maps

Author

Panagiotakopoulos, Theodor, Zafeirakis, Nikolaos, Tsoulea, Iliana-Vasiliki, Groumpos, Peter P., Barbosa, Simone Diniz Junqueira, Editorial Board Member, Filipe, Joaquim, Editorial Board Member, Ghosh, Ashish, Editorial Board Member, Kotenko, Igor, Editorial Board Member, Yuan, Junsong, Editorial Board Member, Zhou, Lizhu, Editorial Board Member, Kravets, Alla G., editor, Groumpos, Peter P., editor, Shcherbakov, Maxim, editor, and Kultsova, Marina, editor

Published

2019

32. Sustainable building evaluation: a case study.

Author

Bahadiroğlu, Ayşegül, Koç, Aybike Yüksel, Parlak, Esra, Larsson, Nils, Kujawski, Woytek, and Unver, Umit

Subjects

*SUSTAINABLE buildings, *EMISSIONS (Air pollution), *CLIMATE change, *BUILDING performance, *ENGINEERING standards

Abstract

The building sector is one of the leading contributors to global climate change. In recent decades, sustainable building assessment systems have been introduced in developed countries to improve the overall performance of buildings and to prevent greenhouse gas emissions, the main culprit of human activities in the current climate change. SBTool is a sustainable building evaluation system that can be calibrated according to the region, project type and phase of development, making SBTool a tailormade assessment system for a specific project. In this study, SBTool was adapted for the first time to an educational facility in Marmara/Turkey climate. The assessment parameters and their weights are arranged according to climate zone, building type, and accommodation characteristics. The created assessment tool was applied analytically to the Engineering Faculty Building of Yalova University/Turkey as a case study. The study showed that the government-run educational facilities could be evaluated with a tool that has 7 Issues, 21 Categories and 45 Criteria after adjustments made to follow its specific regional and local conditions. The assessed building got a Weighted Score of 3.30 points compared to the Target Weighted Score established at 3.08 points. The relative performance score was assigned to "B" which means an acceptable standard for a sustainable building. The methodology of assessment is presented step by step ending up with a graphical interpretation of the evaluation. [ABSTRACT FROM AUTHOR]

Published

2022

33. Energy-passive residential building design in Amman, Jordan.

Author

Albadaineh, Renad Wael

Abstract

In Jordan, the residential sector is responsible for 43% of all power use and 21% of total energy usage. The use of energy for space heating and cooling accounts for more than 60% of residential energy use. The computer-generated residence, a typical one-storey Jordanian home with a functional floor area of 186 m2, is located in Amman and was modelled to be more energy efficient by incorporating renovating techniques to lower heating and cooling demand, attain marginal energy demand, and produce a high-quality indoor living environment. To get at the idea of passive design houses as appropriately depicted in this paper, various passive design tactics and methodologies were employed. Using DesignBuilder simulation software, Revit modelling software, solar energy analysis software, and assessment of the total energy consumption before and after the deployment of passive design approaches, the effects of each retrofit method were evaluated. The results of this study show that the yearly energy savings for heating is about 78%, and the indoor air quality and temperature of the residence can be significantly enhanced compared to its original situation. The total employed energy in the virtual building was scaled down from 56.57 kWh/m2 to 15.25 kWh/m² each year. [ABSTRACT FROM AUTHOR]

Published

2022

34. A Comparative Study of Energy Performance in Educational Buildings in the UAE

Author

Vian Ahmed, Sara Saboor, Fatima Ahmed Almarzooqi, Hessa Ahmed Alshamsi, Mariam Abdalla Alketbi, and Fatema Ahmed Al marei

Subjects

Energy performance, energy efficiency, CO2 emissions, Sustainability, Sustainable practices, Zero Energy Buildings, Engineering economy, TA177.4-185, Building construction, TH1-9745

Abstract

Sustainability has gained popularity and importance around the globe due to the ever-increasing effects of climate change and global warming on Earth. As of the 21st century, human endeavour has caused an enormous amount of damage to the environmental ecological system. Among which, one of the major contributors to the increase in the environmental issues and CO2 emissions are the conventional sources of energy, especially in the built environment. Globally, the built environment accounts for 12 percent of the world’s drinkable water, 40 percent of energy wastage and 35 percent of scarce natural resources, which in turn produces 40 percent of the total global carbon emission. Among which are educational buildings which tend to be a major contributor (as most of these facilities are old and conventionally built in the mid-1900s) Thus, with the education sector being an essential part of society, it becomes important to determine the energy performance and carbon footprint of these buildings. The United Arab Emirates (UAE) vision 2021 highlights the country's approach to the importance of providing the best education and adopting sustainable environmental infrastructure. Therefore, this study adopts a methodological approach based on semi-structured interviews and surveys, in order to compare the energy performance of three educational buildings within Higher Education establishments in the UAE as a case study. The study also evaluates the end user’s awareness of the importance of sustainable practices in the buildings and their preference for these buildings. The findings of this study conclude that Net Zero Energy Buildings (NZEBs) are the most efficient buildings in terms of energy performance, carbon consumption and heat generated. Therefore, it is important that the integration of these types of buildings is considered in educational establishments.

Published

2021

35. Strategies for grid-friendly and uncertainty-adaptive design in zero energy buildings.

Author

Hu, Kai, Yan, Chengchu, Xu, Chao, Li, Wenjun, Ye, Jing, Gong, Yanfeng, and Xu, Yizhe

Abstract

• An optimization method for energy system in zero energy buildings is presented. • The grid-friendly interaction index between building and the grid is introduced. • The uncertainty of design parameters is quantified by Monte Carlo method. • An optimization framework based on the results of deterministic optimization is presented. • The method is applied to an actual ZEB in Hong Kong. The intermittency and fluctuation of renewable energy sources cause large uncertainties in energy generation, not only leading to an energy imbalance between energy generation and utilization in Zero Energy Buildings (ZEBs) but also causing potential risks to the connected electricity grid. To address this issue, we propose a method for optimizing the design of the energy system in ZEBs, which emphasizes grid-friendly interaction with grids and considers the uncertainty quantification in renewable resources and cooling demand. This study introduces the grid-friendly interaction index to evaluate the compatibility of ZEB energy exchanges with the power grid. The aim is to optimize these exchanges for better grid integration. Utilizing 26 years of historical weather data, the Monte Carlo method is used to quantify the uncertainty of design parameters, thereby informing our optimization process. A comprehensive analysis, centered on an actual ZEB in Hong Kong, compares our uncertainty-based design methodology against traditional, deterministic design approach. The results demonstrate that the proposed method can achieve up to a 9 % cost reduction, a 6.8 % reduction in carbon dioxide emissions, and a 10.8 % improvement in grid-friendliness compared to deterministic design schemes. These results affirm the efficacy of the proposed methods in providing appropriate design options to meet diverse reliability demands. [ABSTRACT FROM AUTHOR]

Published

2024

36. The Unsustainable Direction of Green Building Codes: A Critical Look at the Future of Green Architecture

Author

Isaac Guedi Capeluto

Subjects

Green Building Codes, green architecture, sustainable design, energy use, well-being, Zero Energy buildings, Building construction, TH1-9745

Abstract

Buildings are a major contributor to global energy consumption and energy-related carbon dioxide emissions. In light of the climate crisis, changes in the way we design, construct and use buildings are needed to reduce their environmental impact. Green Building Codes (GBCs) and rating systems have been developed around the world as a basis for green building practices. However, several studies raised doubts about the actual performance of certified buildings. Moreover, they use a per unit area approach to assess the use of resources rather than per capita, penalizing small buildings or those with high occupancy, ignoring the concepts of equity and shared common effort which are central to sustainable design. In this paper we propose adjustments to GBCs to encourage new ways of designing and evaluating green buildings. We introduce the Occupancy Correction Factor (OCF) which prioritizes smaller and more densely occupied buildings reducing land use, total operational energy consumption and embodied energy. Results show changes in their energy ratings of one to three levels both up and down, compared to their original ratings. In addition, we propose the prioritization of high-efficiency Low-Energy and Nearly Zero-Energy buildings over Net Zero Energy buildings, encouraging innovative urban design to enhance solar access and electricity production potential on-site or nearby.

Published

2022

37. Integration of CCHP microgrids in NZEB with critical loads under high PQR requirements, a position paper

Author

Rafael Savariego, Antonio Moreno-Munoz, Isabel M. Abascal-Castaneda, M. Isabel González-Cuenca, Carlos Santos Silva, Javier Tobajas-Blanco, Fco. Javier López-Alcolea, Emilio J. Molina-Martínez, Romain Mannini, Stéphane Grieu, Ana Estanqueiro, and David Loureiro

Subjects

Energy storage systems, General Energy, Power quality, Energy management, Zero Energy Buildings, Microgrids

Abstract

In recent years, many projects have been developed to reduce the energy consumption of buildings, both from the point of view of energy efficiency and the integration of renewable energies. However, few projects are related to the problem of integrating DER in environments dominated by high-tech equipment, the so-called ”critical loads”: data centers, railroad stations, airports, and hospitals. The European Interreg Sudoe IMPROVEMENT project aim is to renovate existing public buildings where critical loads predominate, converting them into nearly zero-energy buildings (NZEB), and for this purpose, it integrates combined cooling, heat, and power (CCHP) microgrid with renewable and other distributed energy resources (DER) like hybrid energy storage systems (ESS). With still one year to go before the end of the project, the consortium partners present in this position paper the latest progress of their respective work packages to date. info:eu-repo/semantics/publishedVersion

Published

2023

38. Sustainability in university campus: options for achieving nearly zero energy goals

Author

Fonseca, Paula, Moura, Pedro, Jorge, Humberto, and de Almeida, Aníbal

Published

2018

39. ANALYSIS OF NEARLY ZERO ENERGY RESIDENTIAL BUILDING IN MUSCAT.

Author

Sharif, Hafiz Zafar, Leman, A. M., Krizou, Aissa Nasser, Al-Tarawne, Mohammad Tala't Ahmed, Subbiah, Muthuraman, and AL-Farsi, Muna

Subjects

*DWELLING design & construction, *DWELLINGS, *BUILDING performance, *HOME energy use, *ENERGY consumption, *SIMULATION software, *NATURAL gas, *RESIDENTIAL energy conservation

Abstract

The building sector is the largest consumer of the primary sources of energy worldwide. The most commonly used primary sources of energy to generate electricity are oil, coal, peat, shale, natural gas, nuclear, hydro, renewables, biofuels, and waste. The energy demand by the building sector is about 40% of the world's energy production. Net Zero Energy Buildings (NZEBs) is the best solution recommended by the energy experts to reduce substantial pressure on primary sources of energy contributed by the building sector. There is a marginal gap between estimates made during the design stage and actual energy performance of residential buildings, primarily due to a lack of understanding of the factors affecting energy use and whole building simulations software limitations. The purpose of this research work was to conduct a comparative analysis of a predicted versus actual energy consumption of prototype Net Zero Energy Building (NZEB) constructed at Higher College of Technology, Muscat. Hourly Analysis Program (HAP V4.2) was used to predict energy demand of NZEB at HCT and same size regular house in Muscat. PVWatts calculator was used to determining possible power generation by the PV system installed on the roof in the form of a canopy. The constructed house was tested for one month to perform multiple tasks as per competition requirements in which one of the major tasks was to produce onsite energy production by PV panel's equivalent to the energy consumed by the house. The actual energy consumption results were compared with the simulated result and observed that actual energy demand of house was approximately 20% lower than that predicted by the simulation tool. The comparison of simulation results between NZEB and regular house indicated 61.24% less energy demand of NZEB, mainly due to less HVAC load. The simulation result for BEI of NZEB showed 87.20 kWh/m2/year as compare to 225.1 kWh/m2/year for same size regular house. The simulated result obtained from PVWatts calculator for competition period and actual production of an installed PV system at the top roof showed a minor deviation of 0.73% only. It is also observed from the results during the competition period house exported 1221 kWh energy to the grid. [ABSTRACT FROM AUTHOR]

Published

2020

40. European legislation and incentives programmes for demand Side management.

Author

Castro, Maria de Fátima, Colclough, Shane, Machado, Bruno, Andrade, Joana, and Bragança, Luís

Subjects

*LOAD management (Electric power), *RENEWABLE natural resources, *SMART power grids, *POWER resources, *ENVIRONMENTAL health, *FOSSIL fuels

Abstract

• The way how is the building industry dealing with the concept of Demand Side Management is discussed. • International policies and initiatives are presented. • European initiatives, legislation and incentive programmes are presented. • The implementation of the nZEB requirement using the Passive House standard is presented. • A new approach is proposed - Early Stage Design method to ensure dwellings sustainability. Energy is now intrinsically linked to technological development, given it powers all such systems. The use of fossil fuels to supply the required energy is causing global environmental and health issues and is impacting on all life forms on the planet. Given increasing energy consumption, anthropogenic greenhouse gas emissions are consequentially increasing. Therefore, it is necessary to replace fossil fuels with renewable energies, biofuels and eco materials and related technologies and to try and find a way to develop sustainable zero emission solutions for all areas including constructions, transport and water resources. A critical and evolutionary way of thinking about the energy (and other resources) demand, management and supply is necessary because there are clear concerns about irreversible impacts to the world and a scarcity of the resources as well. Energy supplies should be mostly or entirely through renewable resources and highly efficient technologies put in place to achieve solution such as nearly Zero Energy Buildings (nZEB). At the same time, all the energy and resource use processes should be optimised in order to maximise the benefits, reduce the costs and promote stakeholders (consumers, companies or governments) network, toward a circular economy. This could be the way to supply the demand without increasing the scarcity of the resources and to simultaneously achieve environmental benefits. Therefore, it should be possible to improve productivity with the same amount of resources, by e.g. maximising the potential of smart grids and heuristically develop solutions with stakeholders. The concept of Demand Side Management (DSM) emerged after the energy crisis and it employs solutions such as reducing the daily peak load. At the same time, creating an educational grid is important to change the established paradigms, in order to promote critical thinking about the wasted resources and thinking holistically about overall consumption. This paradigm shift is changing the market, making it more competitive and reducing inefficiency by promoting the efficient use of resources including the deployment of energy storage during the periods of low consumption in daily peak shift. All these issues present a new way of thinking in the path towards sustainability, maximising the circular economy and reducing environmental impacts, making connections and using the Internet of Things to provide more information to all stakeholders. All these changes in social behaviour are related to the rational use of resources and make it easier to improve the existing infrastructures instead of building new ones. This paper analyses the state of the art at the European level in the production and use of renewable resources. A survey and analysis of the incentives to consumers and the policies to encourage the circular economy, and parallel analysis of benefits and drawbacks, was made. It is intended to identify the main forms of intervention and improvement, culminating in a reflection on how they should be applied to improve the expected results and make them more efficient and sustainable. This is intended to be an evolutionary framework of this concept, from the first stage of use of energy to its final utilisation. By approaching the task in a heuristic fashion, it is hoped to make the environment healthier, and it is envisaged that this concept will evolve from a linear to a life cycle approach. [ABSTRACT FROM AUTHOR]

Published

2020

41. A Green and Energy-Efficient Smart Building Driven by Photovoltaic Thermal Panels Connected to the Grid

Author

Behzadi, A., Sadrizadeh, Sasan, Behzadi, A., and Sadrizadeh, Sasan

Abstract

The present paper introduces a new smart building system driven by photovoltaic thermal panels. The concept is to improve the contribution of renewable energy in the local matrix for peak load shaving by having a two-way connection with the local electricity network via a rule-based energy monitoring control design. Besides, the feasibility of removing the electrical storage unit with high investment cost is studied by establishing a dynamic interaction between the energy production and usage components to reduce the energy costs over the year. The system has intelligent thermal energy storage integrated with an electrically-driven coil, heat exchanger, pumps, and several smart valves and control units. The transient system simulation (TRNSYS) package is implemented to assess the practicality of the suggested intelligent model for a building complex in Malmo, Sweden. According to the parametric outcomes, by raising the panel area, while the generated electricity increases, the solar utilization factor falls, indicating conflictive changes among performance metrics. The results also show that the renewable resource covers the building's heating and electricity demands for the majority of the year and that a significant amount of energy is sold to the neighbourhood electricity grid, demonstrating the viability of the introduced intelligent model., Conference paper; Export Date: 14 June 2023; Cited By: 0

Published

2023

42. Approaching nearly zero energy of PV direct air conditioners by integrating building design, load flexibility and PCM.

Author

Li, Sihui, Peng, Jinqing, Wang, Meng, Wang, Kai, Li, Houpei, and Lu, Chujie

Subjects

*PHOTOVOLTAIC power systems, *BUILDING performance, *DATA mining, *ENERGY storage

Abstract

The energy matching of PV driven air conditioners is influenced by building load demand and PV generation. Merely increasing energy performance of building or PV capacity separately may improve the energy balance on a large time resolution, the real-time energy mismatching problem is still serious. In this study, a coordinated optimization method of PV capacity, building design, and load flexibility is proposed for improving the real-time energy matching of PVAC system. Then, a methodology integrating data mining method (XG Boost) and parametric simulation was developed to identify the determinant parameters of PV system and building design, exploring feature importance and correlations. The results of XG Boost indicate that the PV capacity, shape factor, and SHGC are the most critical factors. Finally, based on the optimized building design, the PCM layer was appli ed to improve the real time energy matching. To achieve a goal of 90 % ZEP, the PCM capacity can be decreased by 50.4 % and 62.8 % in Guangzhou and Shanghai in the optimized building. Moreover, the PV capacity can be reduced by 23 % in Guangzhou. The findings of this study provide practical guidance for designing PVAC system coupling with building design and energy storage devices. [ABSTRACT FROM AUTHOR]

Published

2024

43. Critical assessment of large-scale rooftop photovoltaics deployment in the global urban environment.

Author

Kapsalis, Vasileios, Maduta, Carmen, Skandalos, Nikolaos, Wang, Meng, Bhuvad, Sushant Suresh, D'Agostino, Delia, Ma, Tao, Raj, Uday, Parker, Danny, Peng, Jinqing, and Karamanis, Dimitris

Subjects

*GLOBAL warming, *PHOTOVOLTAIC power generation, *CLIMATIC zones, *SKYSCRAPERS, *CLEAN energy, *BUILDING-integrated photovoltaic systems, *TECHNOLOGICAL innovations, *ENERGY consumption

Abstract

In support of the clean energy transition, rooftop photovoltaics (RTPV) deployment has been globally advocated, enabling citizens as energy prosumers within their localised building environment. However, the effectiveness of RTPV implementation is influenced by diverse bioclimatic conditions. Here, we provide a critical climate-related RTPV characterisation across the globe, consisting of a comprehensive assessment of RTPV performance, taking into account global horizontal irradiation (GHI) and local environmental parameters, including space conditioning requirements in different climatic zones. Additionally, we examine the technological advancements aimed at improving efficiency in RTPV systems. Within a meta-data analysis, we find that the RTPV systems offer various advantages in terms of building overall energy performance, particularly in moderate and warm climates. We observe that typical or increased insulation values can offset the RTPV effect in uninsulated roofs. This is essential in regions with cold climates and helps to mitigate increased heating requirements during winters or higher cooling demands during summer nights. A relationship between the ratio of building space coverage to PV surface and GHI is proposed for low-energy buildings to calculate the space requirements for achieving net zero buildings, globally. Moreover, in hot climates, cooling the RTPV surfaces can enhance efficiency by up to 20 % and increase power output by up to 15 %. By advancing RTPV efficiency to 30 % with emerging technologies, the decarbonisation of high-rise buildings can be facilitated, alongside energy efficiency and RTPV implementation measures. Striking a balance between thermal insulation needs, we conclude that RTPV offers wide benefits across different climatic conditions. [Display omitted] • Rooftop PV deployment is crucial for decarbonisation and clean energy transition. • RTPV is energy-beneficial in moderate and warm climate conditions. • RTPV energy drawbacks in cold climate and hot climates can be mitigated. • PV efficiency of 30 % can accelerate the transition to NZEB in all climatic conditions. [ABSTRACT FROM AUTHOR]

Published

2024

44. Review of Zero Energy Building Concept-Definition and Developments in Latin America: A Framework Definition for Application in Panama

Author

Miguel Chen Austin, Katherine Chung-Camargo, and Dafni Mora

Subjects

Zero Energy Buildings, nZEB, NZEB, tropical climate, residential sector, Technology

Abstract

In recent decades, European countries have developed concepts, definitions, and construction technologies for Zero Energy Building (ZEB) that are effective and correspond to their specific climates. Latin American countries are still trying to find adequate solutions which respond to the local climatic, cultural, social, technical, and economic context. As such, this paper aims to establish the basis of the minimum energy efficiency and the renewable threshold for the definition of ZEB in order to better understand the application in Panama, based on assessing the energy regulations implemented in Panama. To achieve this aim, a review concentrated on the concept-definition and implementation adopted by Latin American countries is presented first before the paper converges into defining a framework for application in Panama. Finally, a case-study-based theoretical framework proposing a ZEB definition for Panama is discussed. The results of this study showed a net primary energy balance, of which the range falls into a plus energy building definition, indicating that all of the cases studied could supply their electricity needs using Photovoltaic generation. All dwellings studied have the potential to become a plus energy building, depending on the available roof surface area. Finally, a strengths, weaknesses, opportunities and threats analysis is presented in order to assess and support the introduction of such a ZEB definition and framework.

Published

2021

45. Economic Evaluation of Small Public Office Buildings with Class 1 of Zero Energy Building (ZEB) in Korea by Reflecting Life Cycle Assessment (LCA)

Author

Kim, Duhwan Lee, Jaemoon Kim, and Young Il

Subjects

small office buildings, zero energy buildings, ZEB certification, life cycle assessment, Net Present Value

Abstract

This study summarizes the technology level and economic feasibility of two small 500 m2 public office buildings that achieved a first-class Zero Energy Buildings (ZEB) certification for the first time in Korea. In addition, a Life Cycle Assessment (LCA) reflecting the ZEB performance in the operation stage was analyzed, and the LCA factors considering the characteristics of small buildings were reviewed. Moreover, an economic analysis was performed through a Net Present Value (NPV) by reflecting the ZEB and LCA, and the results showed little economic feasibility. However, adding the environmental costs calculated through the LCA to the existing energy-saving costs could offset an additional 11.6–11.7%. Therefore, including the environmental impact and cost through these LCA evaluation techniques could be a positive step toward increasing the effectiveness of ZEB applications. This study is significant in that it conducted a comprehensive analysis through ZEB and LCA in terms of carbon reduction for small buildings that achieved a first-class ZEB certification, but it is limited to only two cases.

Published

2023

46. Zero energy building (ZEB) in a cooling dominated climate of Oman: Design and energy performance analysis.

Author

Al-Saadi, Saleh Nasser and Shaaban, Awni K.

Subjects

*SUSTAINABLE design, *ELECTRIC power distribution grids, *CLIMATOLOGY, *BAND gaps, *ENERGY consumption, *RENEWABLE energy sources

Abstract

Zero energy buildings (ZEBs) are targeted by several developed countries around the world which consequently promotes the progress toward achieving ZEBs. The concept of ZEBs is, however, uncommon in developing economies such as Oman. In 2011, The Research Council of Oman has announced a competition to design, construct and operate buildings that embrace sustainability principles. The first five eco-friendly buildings were designed and constructed by academic institutions in different climatic conditions of Oman. This project has significantly contributed toward raising awareness of energy efficiency and renewable energy systems in buildings. This paper outlines the design of sustainable energy systems of one of these five buildings. The ZEB prototype is located at the Sultan Qaboos University campus in Muscat, which is an extremely hot climate as classified by the ASHRAE Standard 169-2013. The ZEB building was designed with full manipulation of natural energy. This paper also reports the experimental results of its one year of operation. The results showed that energy use intensity (EUI) of 103 kWh/m2 was achieved by this building. The building was less than 3% from achieving its net-zero energy source/site/emissions status. Nonetheless, it was able to achieve a positive energy cost status because of the financial credits received from the exported energy, which is subjected to high cost feed-in tariffs. When grid interaction was considered, 40% of the building load was met by site generation. For 33% of the time, this building was independent of the electrical grid, which is comparable to other net-zero energy buildings located in other climates. While several experimental studies for ZEB performance have been described in literature for heating dominated climates, very few experimental studies have been published for cooling dominated climates. Hence, this study aims to fill the gap in the knowledge of energy performance of ZEBs located in this region. • The design of sustainable energy systems for ZEB in a hot climate is described. • ZEB is feasible in cooling dominated climate. • Experimental result for one year of operation for a prototype ZEB is described. • For 33% of the time, the building was independent of the electrical grid. 40% of the building load was met by the site generation. [ABSTRACT FROM AUTHOR]

Published

2019

47. Pathways to plus-energy buildings in Algeria: design optimization method based on GIS and multi-criteria decision-making.

Author

Mokhtara, Charafeddine, Negrou, Belkhir, Settou, Noureddine, Gouareh, Abderrahmane, and Settou, Belkhir

Abstract

In recent years, net zero or plus-energy buildings (PEB) have been widely analyzed and discussed for their benefits of increasing energy savings and reducing greenhouse gas emissions. A successful transition to energy-efficient buildings must, however, develop an efficient method that examines technical, economic, environmental and social criteria. In this paper, a method for design optimization based on spatial analysis combined with multi-criteria decision-making was proposed for achieving plus-energy buildings in Algeria. To apply the proposed method, a single family residential building was chosen. First, the annual energy consumption of the building at 40 locations was evaluated and the results are then interpolated for the whole country. The best energy efficiency measures and renewable energy are then chosen using the Analytic Hierarchy Process (AHP) method. Finally, energy balance and spatial analysis were carried out based on the geographical information system. The results showed the energy plus target was achieved in large parts of the country using a high-performance envelope, more efficient appliances and solar energy (solar photovoltaic and thermal). In addition, the southern provinces, mainly Adrar, Tindouf, Bechar, Ouargla, and Illizi, have identified the most suitable areas for setting up new buildings with an energy-plus target. In addition, applying the method will reduce the overall energy demand by 43 % and reduce GHG emissions in the country by around 23 % by 2030. Therefore, the method will have a significant impact on sustainability locally and worldwide. [ABSTRACT FROM AUTHOR]

Published

2019

48. Transitioning to a 100% renewable energy system in Denmark by 2050: assessing the impact from expanding the building stock at the same time.

Author

Drysdale, David, Mathiesen, Brian Vad, and Paardekooper, Susana

Subjects

*RENEWABLE energy sources, *DWELLINGS, *POWER resources, *ENERGY consumption of buildings, *ELECTRICITY

Abstract

Residential and service (office) buildings consume a large proportion of primary energy in Europe in the form of electricity and all other energy carriers. In response to this, the concept of near Zero Energy Buildings (nZEB) has been developed. These buildings have very low energy demands and integrate renewable energy to supply residual demand. nZEBs aim to increase energy efficiency from a demand-side user perspective. When looking at the entire energy system, there are also energy efficiency gains to be achieved on the supply-side. For example, from a district heating system. If an energy system becomes more efficient on the supply-side, then the question is how much energy needs to be saved on the demand-side, for instance by low energy buildings such as nZEBs. The purpose of this paper is to analyse and understand the implications from building new low energy buildings, i.e. nZEBs, within an energy system that is (a) transitioning to 100% renewable energy and (b) has substantially improved supply-side energy efficiency. A case study from Denmark is used to understand the outcome for the energy system when these new buildings are built in this context. The methodology and results of this study could be replicated for other European countries as well. The analysis looks at the total energy system heat savings, costs and biomass consumption. The paper shows that these new low energy buildings with very low heat demand do not deliver the expected benefits for the 100% renewable energy system transition in Denmark. This is due to the increased efficiency and flexibility of the energy supply system in the future. However, deep renovations of existing buildings are necessary. Furthermore, this paper demonstrates based on the Danish case, that as European countries decarbonise their energy systems over the next decades, they will need to carry out detailed energy system analysis to determine the extent to which heat demand should be reduced in buildings within the context of the transitioning energy system. [ABSTRACT FROM AUTHOR]

Published

2019

49. Introduction of a Methodology for Deep Energy Retrofitting of Post-War Residential Buildings in Central Europe to Zero Energy Level

Author

Antonin Lupisek, Martin Volf, Petr Hejtmanek, Katerina Sojkova, Jan Tywoniak, and Peter Op't Veld

Subjects

deep energy retrofitting, zero energy buildings, energy efficiency, residential buildings, renovation strategy, Transportation and communications, HE1-9990, Science, Transportation engineering, TA1001-1280

Abstract

Buildings are responsible for 35% of greenhouse gas emissions released in Europe. The highest potential for reduction of the environmental impacts is in the existing buildings' energy efficiency improvement. The paper introduces a development of new methodology for a rapid deep energy retrofitting of existing buildings applicable to residential housing stock in Central Europe. It briefly describes the steps from production of building information model of existing building to complete renovation. It presents experience from pre-production phases on a case study from the Czech Republic. Technical and non-technical barriers to be solved in the near future are summarised in the discussion.

Published

2016

50. Technical Feasibility Study for Zero Energy K-12 Schools

Author

Goldwasser, David

Published

2016