Pythagoras project: Development of an innovative training package on Indoor Environment Quality

The aim of the Pythagoras project is the development and assessment of Greek national training material in the sector of indoor environmental quality. The need for education in this specific sector is dictated by the significant indoor environment deterioration and associated health hazards, which are caused by low ventilation levels, combined with the use of many modern building materials that aggravate pollutants emissions. Early in the project, a review is undertaken of the international literature and the syllabuses of foreign research and educational institutions active in indoor environment quality issues. At the same time, the requirements of the Greek educational and broader society, related to issues of indoor pollution and health, are determined. A training methodology is consequently developed, with the objective to optimally cover all the parameters associated with the indoor environment quality, for trainees of various disciplines. The training material is produced both in printed (book) and integrated electronic (e-learning) format. Additionally, four seminars are organized covering the respective sections of the training package. The training package is being assessed both by the trainees but also by international experts in the sector of indoor environment quality

A Semi-Distributed Electric Demand-Side Management System with PV Generation for Self-Consumption Enhancement

This paper presents the operation of an Electrical Demand-Side Management (EDSM) system in a real solar house. The use of EDSM is one of the most important action lines to improve the grid electrical efficiency. The combination between the EDSM and the PV generation performs a new control level in the local electric behavior and allows new energy possibilities. The solar house used as test-bed for the EDSM system owns a PV generator, a lead-acid battery storage system and a grid connection. The electrical appliances are controllable from an embedded computer. The EDSM is implemented by a control system which schedules the tasks commanded by the user. By using the control system, we define the house energy policy and improve the energy behavior with regard to a selected energy criterion, self-consumption. The EDSM system favors self-consumption with regard to a standard user behavior and reduces the energy load from the grid

Embedding technologies for improving Nature-Based Solutions performance and fostering social inclusion in urban greening strategies: Augmented NBS for cities

Nature-Based Solutions (NBS) have been at the forefront of the European Commission policies since 2015 (Eggermont et al., 2015) as a specific thematic area for developing sustainable cities strategies either from social inclusivity or innovative urban technology standpoints (European Commission, 2023). NBS have been considered as innovative solutions within the ambition to enact a new ambit of research for NBS and implications on urban transition (Zwierzchowska et al., 2022). Nonetheless, the technological advancements related to NBS implementation are increasingly demanded in correspondence to the need to improve and mainstream NBS impacts at architectural, urban planning and strategic levels (Hölscher et al., 2023). The experience of NBS in place has increasingly matured with many applications in practice (Mahmoud et al., 2022), which have enabled the development of new skills and related services and the refinement of new technologies and technical solutions (Wellmann et al., 2022). The technological support for NBS has become evident throughout the way people experience urban nature in their everyday lives (Ahlborg et al., 2019, Li and Nassauer, 2021). In this special issue, the theme of technology and its uses within urban planning and green infrastructure was investigated. We promote the concept of "Augmented NBS" that is, NBS supported and enhanced by the use of technology, whether incorporated directly into the solution in the field as a prosthesis of the natural element or deployed remotely through digital analysis tools or remote sensing (Mahmoud et al., 2024). Hence, the special issue embraces a broad conceptualization of the use of technology applied "in" and "for" NBS, including digital placemaking, air quality, economic benefits, health and wellbeing, and digital mapping and decision-making tools for landscape design. It is aimed to collect best practices on how technologies, in different ways, can enhance the performance and impact of NBS. From March 2022 till July 2023, this special issue collected several articles from the socio-ecological-technological aspects and NBS themes

Public building energy efficiency - an IoT approach

Buildings play an important role in energy consumption, mainly in the operation phase. Current development on IoT allows implementing sustainable actions in building towards savings, identify consumption patterns and relate consumption with space usage. Comfort parameters can be defined, and a set of services can be implemented toward the goals of saving energy and water. This approach can be replicated in most buildings and considerable savings can be achieved thus contributing to a more sustainable world without negative impact on building users’ comfort.info:eu-repo/semantics/acceptedVersio

Analyzing the Impact of Urban Planning and Building Typologies in Urban Heat Island Mitigation

Urban and building typologies have a serious impact on the urban climate and determine at large the magnitude of the urban overheating and urban heat island intensity. The present study aims to analyze the impact of various city typologies and urban planning characteristics on the mitigation of the urban heat island. The effect of the building height, street width, aspect ratio, built area ratio, orientation, and dimensions of open spaces on the distribution of the ambient and surface temperature in open spaces is analyzed using the Sydney Metropolitan Area as a case study for both unmitigated and mitigated scenarios. Fourteen precincts are developed and simulated using ENVI-met the simulation tool. The ambient temperature, surface temperature, and wind speed are extracted. The parameter ‘Gradient of the Temperature Decrease along the Precinct Axis’ (GTD) is introduced to study the cooling potential of the various precincts. In the mitigated precincts, the GTD ranges between 0.01 K/m to 0.004 K/m. In the non-mitigated precincts, the GTD ranges between 0.0093 K/m to 0.0024 K/m. A strong correlation is observed between the GTD of all the precincts, with and without mitigation, and their corresponding average aspect ratio, (Height of buildings to Width of streets). The higher the aspect ratio of the precinct, the lower the cooling potential. It is also observed that the higher the Built Area Ratio of the precincts, the lower the cooling contribution of the mitigation measures

Examining the benefits and barriers for the implementation of Net Zero Energy settlements

The transition of the Net Zero Energy (NZE) concept from building to settlement scale has been theoretically approached in a number of studies. This paper examines the benefits and barriers associated with the implementation of the NZE concept at a settlement scale, by adopting a comprehensive approach for the design, construction, and monitoring of NZE settlements that was developed in the EU Horizon 2020 ZERO-PLUS project and implemented in four case studies. First, the ZERO-PLUS approach is presented, followed by an analysis of associated benefits and encountered barriers. Next, the roles of different stakeholders involved in the process are identified through stakeholder analysis. Finally, new dynamics that emerge and are critical to the successful implementation of NZE settlements are discussed. The ZERO-PLUS approach leads to achieving NZE settlements with an initial cost that is on average 16% lower than the cost of a typical NZEB, while achieving a net regulated energy consumption of less than 20 kWh/m2/year and renewable energy production of more than 50 kWh/m2/year. The implementation of NZE settlements revealed two main issues: 1) the external barriers that were raised by the planning policies and regulations; and 2) the challenge of managing and integrating the needs and requirements of project stakeholders. To overcome these barriers while reaping the benefits of the approach, the management of such projects needs to focus from the outset on the establishment of a project management structure that will ensure the coordination and integration of various stakeholders. The use of a standardized collaboration protocol from the preliminary design stage is recommended to facilitate future projects. Simultaneously, regulations need to be updated towards facilitating NZE settlement implementation

A Practical Guide to the New European Bauhaus Self-assessment Method and Tool

This handbook provides a complete guide to the New European Bauhaus (NEB) self-assessment method, designed to promote the three NEB dimensions, namely sustainability, beauty, and inclusiveness, in the built environment of Europe and beyond. The handbook comes together with an online tool allowing to evaluate the performance of projects and support their improvement. The online tool is seen as the basis to establish a dialogue between all involved stakeholders, and the grounds for defining minimum performance levels within the NEB framework. Advanced targets and indices are proposed to help professionals assess all aspects of the three NEB dimensions in buildings and living spaces, promote sustainable economic and financial activities, overcome local constraints, and improve the quality of life of the European citizens, indoors and outdoors, through a built environment designed to be affordable, aesthetically appealing, healthy, comfortable, and accessible for everyone, also addressing safety, functionality under hazards, adaptation to new functions. Acknowledging the complexity of a comprehensive evaluation, and understanding the variability of metrics associated with the three NEB dimensions across different project types, scales, and geographical regions, the self-assessment method is structured hierarchically to provide feedback with three interconnected assessment levels: indicator, key performance indicator, and dimension. Specifically, the method defines three spatial scales, i.e. building, neighbourhood, and urban, and delineates two project types, i.e. newbuild and renovation. Supporting the self-assessment process, the online tool aims to facilitate the user and simplify the evaluation process while upholding the method integrity and effectiveness. This handbook offers a thorough guidance on the New European Bauhaus self-assessment method and its underlying principles. It covers assessment targets, indicators, key performance indicators, evaluation methods, and measurement units. Additionally, the handbook includes illustrative examples, empowering the interested users with the knowledge necessary to perform the evaluation effectively. The handbook primarily targets professionals engaged in both the delivery phase (design, construction, and commissioning) and the operational phase (operations and maintenance). Project managers, architects, engineers, and consultants are anticipated to play an active role in gathering and generating the information needed for the self-assessment. However, various stakeholders throughout the entire building lifecycle and supply chains are also expected to participate, benefit from, and be influenced by the assessment, including product manufacturers, main and specialist contractors, policymakers, building users and the local community members directly impacted by the project outcomes. The method is not intended to foster competition or reward high-scoring projects; rather, its purpose is to drive continuous improvement in the built environment quality and align projects with the NEB objectives. Whereas users are expected to aim at the highest performance in the self-assessment, the decision of focusing more on some performance indicators rather than others is finally left each user. To emphasise the significance of a balanced performance across all three dimensions of projects, the possibility of obtaining a global performance combining the three NEB dimension scores was intentionally excluded

A Practical Guide to the New European Bauhaus Self-assessment Method and Tool

This handbook provides a complete guide to the New European Bauhaus (NEB) self-assessment method, designed to promote the three NEB dimensions, namely sustainability, beauty, and inclusiveness, in the built environment of Europe and beyond. The handbook comes together with an online tool allowing to evaluate the performance of projects and support their improvement. The online tool is seen as the basis to establish a dialogue between all involved stakeholders, and the grounds for defining minimum performance levels within the NEB framework. Advanced targets and indices are proposed to help professionals assess all aspects of the three NEB dimensions in buildings and living spaces, promote sustainable economic and financial activities, overcome local constraints, and improve the quality of life of the European citizens, indoors and outdoors, through a built environment designed to be affordable, aesthetically appealing, healthy, comfortable, and accessible for everyone, also addressing safety, functionality under hazards, adaptation to new functions. Acknowledging the complexity of a comprehensive evaluation, and understanding the variability of metrics associated with the three NEB dimensions across different project types, scales, and geographical regions, the self-assessment method is structured hierarchically to provide feedback with three interconnected assessment levels: indicator, key performance indicator, and dimension. Specifically, the method defines three spatial scales, i.e. building, neighbourhood, and urban, and delineates two project types, i.e. newbuild and renovation. Supporting the self-assessment process, the online tool aims to facilitate the user and simplify the evaluation process while upholding the method integrity and effectiveness. This handbook offers a thorough guidance on the New European Bauhaus self-assessment method and its underlying principles. It covers assessment targets, indicators, key performance indicators, evaluation methods, and measurement units. Additionally, the handbook includes illustrative examples, empowering the interested users with the knowledge necessary to perform the evaluation effectively. The handbook primarily targets professionals engaged in both the delivery phase (design, construction, and commissioning) and the operational phase (operations and maintenance). Project managers, architects, engineers, and consultants are anticipated to play an active role in gathering and generating the information needed for the self-assessment. However, various stakeholders throughout the entire building lifecycle and supply chains are also expected to participate, benefit from, and be influenced by the assessment, including product manufacturers, main and specialist contractors, policymakers, building users and the local community members directly impacted by the project outcomes. The method is not intended to foster competition or reward high-scoring projects; rather, its purpose is to drive continuous improvement in the built environment quality and align projects with the NEB objectives. Whereas users are expected to aim at the highest performance in the self-assessment, the decision of focusing more on some performance indicators rather than others is finally left each user. To emphasise the significance of a balanced performance across all three dimensions of projects, the possibility of obtaining a global performance combining the three NEB dimension scores was intentionally excluded

Bioclimatic Architecture and Urban Morphology. Studies on Intermediate Urban Open Spaces

This paper deals with the interactions between biophysical and microclimatic factors on the one hand with, on the other, the urban morphology of intermediate urban open spaces, the relationship between environmental and bioclimatic thermal comfort, and the implementation of innovative materials and the use of greenery, aimed at the users’ well-being. In particular, the thermal comfort of the open spaces of the consolidated fabrics of the city of Rome is studied, by carrying out simulations of cooling strategies relating to two scenarios applied to Piazza Bainsizza. The first scenario involves the use of cool materials for roofs, cladding surfaces, and pavement, while the second scenario, in addition to the cool materials employed in the first scenario, also includes the use of greenery and permeable green surfaces. The research was performed using summer and winter microclimatic simulations of the CFD (ENVI-met v. 3.1) type, in order to determine the dierent influences of the materials with cold colors, trees, and vegetated surfaces on the thermal comfort of the urban morphology itself. Meanwhile, the comfort assessment was determined through the physiological equivalent temperature (PET) calculated with the RayMan program. The first scenario, with the use of cool materials, improves summer conditions and reduces the urban heat island eect but does not eliminate thermal discomfort due to the lack of shaded surfaces and vegetation. The second scenario, where material renovations is matched with vegetation improvements, has a slightly bad eect on winter conditions but drastically ameliorates the summer situation, both for direct users and, thanks to the strong reduction of the urban heat island eect, to urban inhabitants as a whole

An internet of things and blockchain based smart campus architecture

Rapid development in science and information technologies, such as the Internet of things, has led to a growth in the number of studies and research papers on smart cities in recent years and more specifically on the construction of smart campus technologies. This paper will review the concept of a smart campus, discuss the main technologies deployed, and then propose a new novel framework for a smart campus. The architecture of this new smart campus approach will be discussed with particular consideration of security and privacy systems, the Internet of things, and blockchain technologies