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The escalation in demand for buildings in tropical zones has risen resulting from global population growth. Moreover, the construction industry is under growing pressure to adapt sustainable practices. Hence, this research aims to investigate how Circular Economy (CE) principles can be converged with Tropical Design Strategies (TDS) to enhance sustainability within the construction industry.

Qualitative approach was employed with three rounds of Delphi technique, following semi-structured expert interviews. Collected data were analysed through content analysis.

Four passive design strategies were explored as the most suitable strategies for building designs in the tropical regions. To amalgamate passive design strategies of Tropical Designs (TD) with the most practicable CE R principles, 23 number of methods were proposed to each passive design strategy. Furthermore, 11 enablers were revealed in converging TD with CE. Among them, green building design, advanced design software and bioclimatic designs are the enablers which are applicable for all the design strategies.

To the best of the authors’ knowledge, this research is the first kind of research which was done converging three concepts of CE, TD and sustainability. Moreover, this research defined various approaches on how to integrate CE R principles with each identified passive design strategy as an influential approach for ameliorating sustainability. This research contributes to the practice by proposing methods to building designers and architects on how to design buildings in tropical regions following CE principles while ensuring sustainability.

This review investigates the significance of passive solar systems and bioclimatic building designs in improving thermal comfort across various African regions. The study evaluates current papers and publications, focusing on best practice standards, scientific developments and the possibility of achieving maximum thermal comfort across varied temperature zones.

This research utilised a systematic approach to analyse passive solar systems and African bioclimatic design. It involved a review of 175 documents sourced from the Web of Science (WOS) and Scopus databases, focusing on peer-reviewed publications from 1992 to 2023 as well as the Regulations and Standards for Thermal Comfort established in African countries.

The study shows how integrating passive solar systems into bioclimatic architecture greatly increases thermal comfort and lowers energy consumption in African buildings. Nevertheless, significant research gaps exist in using these systems in different African climates. Maintaining and modifying passive solar systems is essential to tackling the distinct environmental issues faced by the continent.

While this review provides a thorough analysis, it acknowledges the complexity of local settings and construction practices, recognising potential limitations in the available literature. The implications include a call for further research and technological advancements to address these limitations and refine passive solar systems for optimal performance.

This study bridges knowledge gaps about how passive solar systems and bioclimatic design principles can be efficiently used across various African climates and areas. Furthermore, it incorporates recent advances and a thorough review procedure to ensure that findings are current and relevant.

The need to design buildings with due consideration for bioclimatic and passive design is central to promoting sustainability in the built environment from an energy perspective. Indeed, the energy and atmosphere considerations in building design, construction and operation have received the highest consideration in green building frameworks such as LEED and BREEAM to promote SDG 9: Industry, Innovation and Infrastructure and SDG 11: Sustainable Cities and Communities and contributing directly to support SDG 13: Climate Action. The research literature is rich of findings on the efficacy of passive measures in different climate contexts, but given that these measures are highly dependent on the prevailing weather conditions, which is constantly in evolution, disturbed by the climate change phenomenon, there is pressing need to be able to accurately predict such changes in the short (to the minute) and medium (to the hour and day) terms, where AI algorithms can be effectively applied. The dynamics of the weather patterns over seasons, but more crucially over a given season means that optimum response of building envelope elements, specifically through the passive elements, can be reaped if these passive measures can be adapted according to the ambient weather conditions. The use of representative mechatronics systems to intelligently control certain passive measures is presented, together with the potential use of artificial intelligence (AI) algorithms to capture the complex building physics involved to predict the expected effect of weather conditions on the indoor environmental conditions.

Ongoing research in computational design synthesis of passive dynamic systems aims to automatically generate robotic configurations based on a given task. However, an automated design-to-fabrication process also requires a flexible fabrication method. This paper aims to explore designing and fabricating passive dynamic walking robots and all necessary components using single-material fused deposition modeling (FDM). Being able to fabricate all components of a robot using FDM is a step toward the goal of automated design and fabrication of passive dynamic robots.

Two different configurations of passive dynamic walking robots are re-designed to be fabricated using FDM. Different robotic joint assemblies are designed and tested. To arrive at feasible solutions, a modular design approach is chosen and adjustability of components after printing is integrated in the design.

The suitability of FDM for printing passive dynamic robots is shown to depend heavily on the sensitivity of the configuration. For one robot configuration, all components are printed in one job and only little assembly is needed after printing. For the second robot configuration, which has a more sensitive gait, a metal bearing is found to increase the performance substantially.

Printable, monolithic mechatronic systems require multi-material printing, including electronics. In contrast, passive dynamic systems not only have the potential to save energy and component cost compared to actuated systems but can also be fabricated using single-material FDM as demonstrated in this paper.

The study aims to synthesize findings from over two decades of research, highlighting key trends, progress, innovations, methodologies and challenges in bioclimatic design strategies and their interconnection with building environmental performance across the world.

This systematic review examines advancements in bioclimatic design strategies aimed at enhancing the environmental performance of buildings from 2000 to 2023 (n = 1,069). The methodology/approach involves a comprehensive analysis of literature from the SCOPUS database using bibliometric analysis, identifying trends, thematic evolution, keyword clusters and pivotal strategies such as passive solar design, natural ventilation, green roofs and thermal mass utilization.

The review highlights significant progress in several areas, including improved simulation/modeling tools for passive solar design, advanced computational fluid dynamics models for natural ventilation optimization, and the integration of green roofs with photovoltaic systems for increased building energy efficiency. Additionally, the use of phase change materials and high-performance glazing has reduced heating and cooling loads, while real-time optimization technologies have enhanced building performance and led to energy savings.

The study recognizes limitations where the effectiveness of bioclimatic strategies varies across different climates. For example, passive solar design is highly effective in temperate climates but less so in tropical regions. Global differences in design preferences and building types and practices impact the applicability of bioclimatic strategies and traditional building methods in some cultures may not easily integrate with modern approaches, affecting their implementation and effectiveness. Furthermore, practical implications highlight the potential for reduced reliance on artificial heating, cooling and lighting systems, while social implications underscore the role of bioclimatic design in promoting sustainable construction practices.

Practical implications highlight the potential for reduced reliance on artificial heating, cooling and lighting systems.

Social implications underscore the role of bioclimatic design in promoting sustainable construction practices.

This review offers a detailed analysis of bioclimatic design evolution, highlighting trends such as adaptive building designs and smart materials. This study serves as a crucial resource for architects, engineers and policymakers, advocating for innovative, climate-responsive design solutions to mitigate the environmental impact of the built environment and address challenges related to climate change and urbanization.

This paper aims to understand the effect of different foundation designs of passive house on the resultant thermal bridges, at the junction between a wall and a slab on grade.

The linear thermal transmittances of some newly developed foundations of passive house are determined. The investigated foundation designs are L-element, U-element and foundation with foam glass technique.

It is found that the special design of passive house foundation can considerably influence the heat flow through thermal bridges. In this context, it is proposed a new foundation design of passive house, which has relatively low heat loss through thermal bridges. The results are compared with the “default” ISO values used to evaluate the effect of thermal bridges in typical buildings. It is found that there is large difference between the calculated linear thermal transmittances at the investigated foundations of passive house as compared to typical buildings.

The results can hopefully be used to improve the energy efficiency of the passive house.

Sustainable solution of buildings.

A new foundation design of passive house is suggested to reduce heat loss through thermal bridges.

Implementation of the concept of passive solar heating design in dwellings has the potential to reduce energy consumption and reduce carbon emissions at little or no cost to the developer but with real benefit to the occupier. The aim of this paper is to investigate the possible benefits to be gained by the application of passive solar heating concepts to the orientation and fenestration of domestic buildings.

The approach used has been to select a simple domestic building designed to current building regulations and apply to it modifications which embody the principles of passive solar heating design. The anticipated performance of the modified building has then been compared with that of its counterpart of conventional configuration by application of a number of currently available simulation models. This study forms part of the Department of Trade and Industry sponsored Knowledge Transfer Partnership between Coventry University and Kenneth Holmes Associates, Chartered Architects.

It is predicted that by careful selection of orientation of a domestic building and modification of its layout, in order that glazing is strategically located, it is possible to effect significant improvements in energy consumption. There is some variation in the output of the alternative techniques but they present a common overall result.

The solutions are purely predictive and it would be of great value if the outcomes could be evaluated by medium term measurement of the performance of dwellings constructed to the proposed design principles.

The concept under analysis could, at little or no cost, result in reduced energy demand in domestic buildings. In the current environmental climate, even modest improvements should be of considerable interest to designers and developers.

Draws upon alternative approaches to passive solar heating design in dwellings and reaches conclusions based on the application of these different approaches to a real live case study.

Several calls have been everywhere asking for proper use of passive design tools like shading devices, insulation, natural ventilation and solar panels in building architecture of hot-dry area in order to improve the thermal performance of indoor spaces. This paper examines the effect of these passive tools on indoor thermal performance which in turn helps arrange thermal priorities properly. Herein, basic principles of Successive Integration Method (SIM) have been utilized for an integrated design of two floors with small openings integrated with floor cooling, solar panels, natural ventilation, shading devices, and insulation. As a result, create priorities of passive tools that are structured consequently for ventilation, insulation, solar panels, and shading devices. This structure could guide designers and builders to set their priorities for the new development of building construction.

This chapter describes the approach to sustainable rail passenger rolling stock in terms of interior passive safety requirements within the European market. It is intended to give the background and logistical approach for the future introduction of a standard as an aid for the design and validation of the interiors of passenger rail vehicles. Also discussed is the acceptance of the proposed European-based standard into the regulatory system of the technical specifications for interoperability. Methodologies for design assessment and validation will be discussed. This chapter is intended to encourage an acceptance of the standard for interior passive safety as a realistic and cost-effective method of improving rail vehicle safety in terms of the passenger interfaces with the rail stock interior.

The study aims to tackle Egypt's rising electricity consumption due to climate change and population growth, focusing on the building sector, which accounts for up to 60% of the issue, by developing new energy-efficient design guidelines for Egyptian buildings.

This study comprises six key steps. A literature review focuses on energy consumption and efficiency in buildings, monitoring a single-family building in Cairo, using Energy Plus for simulation and verification, performing multi-objective optimization, comparing energy performance between base and controlled cases, and developing a localized version of the Passive House (PH) called Energy Efficiency Design Criteria (EEDC).

The research shows that applying the (EEDC) suggested by this study can decrease energy consumption by up to 58% and decrease cooling consumption by up to 63% in residential buildings in Egypt while providing thermal comfort and reducing greenhouse gas emissions. This can benefit users, alleviate local power grid strain, contribute to Egypt's economy, and serve as a model for other countries with similar climates.

To date, no studies have focused on developing energy-efficient design standards tailored to the Egyptian climate and context using the Passive House Criteria concept. This study contributes to the field by identifying key principles, design details, and goal requirements needed to promote energy-efficient design standards for residential buildings in Egypt.