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Climate change means that buildings must greatly reduce their energy consumption. It is however paradoxical that climate mitigation in Denmark has created negative energy and indoor climate problems in housing that may be made worse by climate change. A literature review has been carried out of housing schemes where climate mitigation was sought through reduced space heating demand, and it is shown that extensive problems with overheating exist. A theoretical study of regulative and design strategies for climate mitigation in new build housing has therefore been carried out, and it is shown that reducing space heating with high levels of thermal insulation and passive solar energy results in overheating and a growing demand for cooling.

Climate change is expected to reduce space heating and increase cooling demand in housing. An analysis of new build housing using passive solar energy as a climate mitigation strategy has therefore been carried out in relation to future climate change scenarios. It is shown that severe indoor comfort problems can occur, questioning the relevance of passive solar energy as a climate mitigation strategy. In conclusion, a theoretical study of the interplay between climate adaptation and mitigation strategies is carried out, with a cross-disciplinary focus on users, passive design and active technologies. It is shown that the cumulative use of these strategies can create an adaptation buffer, thus eliminating problems with overheating and reducing energy consumption. New build housing should therefore be designed in relation to both current and future climate scenarios to show that the climate mitigation strategies ensure climate adaptation.

This study aims to analyze the technical, environmental, economic and thermal comfort impacts of implementing passive measures and heating systems in Ciudad Verde, a large-scale social housing project located at the periphery of Bogota, Colombia.

A system dynamics (SD) model is proposed to evaluate scenarios through counterfactual experiments, including technical, environmental and economic components. Model inputs are obtained from building energy simulation models and data collected from official reports, public policy documents and construction records.

Results suggest that the use of heating systems is the best choice to achieve thermal comfort conditions throughout the day. However, both the capital expenditures and CO₂ emissions associated with such system make their adoption very difficult. In line with that, the use of heating systems in combination with passive measures stands out as a viable solution since their costs are affordable and their use contributes to reducing CO₂ emissions.

The proposed model recreates the dynamics underlying social housing construction processes, the adoption of heating systems and passive measures in low-income dwellings and their corresponding impact on CO₂ emissions and indoor thermal comfort conditions. The model can be employed as a support tool in the formulation of social housing policies associated with thermal comfort specifications. In this way, the model represents a first step toward incorporating thermal-related variables into the decision-making processes related to social housing planning and development.

In recent years, there have been a growing number of projects and initiatives to promote the development and market introduction of low and net-zero energy solar homes and communities. These projects integrate active solar technologies to highly efficient houses to achieve very low levels of net-energy consumption. Although a reduction in the energy use of residential buildings can be achieved by relatively simple individual measures, to achieve very high levels of energy savings on a cost effective basis requires the coherent application of several measures, which together optimise the performance of the complete building system. This article examines the design process used to achieve high levels of energy performance in residential buildings. It examines the current design processes for houses used in a number of international initiatives. The research explores how building designs are optimised within the current design processes and discusses how the application of computerised optimisation techniques would provide architects, home-builders, and engineers with a powerful design tool for low and net-zero energy solar buildings.

The study ' s purpose is to review and discuss limitations of “strategic niche management” (SNM) success factors in relation to the experiences of an enterprise network to improve niche development for integrated design concepts.

The emergence of a successful passive house innovation network in the Flemish Region is described. The innovation journey of the network is related to success factors detected in SNM literature regarding market niche development.

The study identifies additional success factors for systemic innovation, such as involving small- and medium-sized innovators and demonstration projects and using a dedicated regional enterprise network.

The qualitative analysis specifically reflected on SNM success factors such as envisioning, learning, and network composition and formation. The study confirms the importance of these success factors by means of one detailed innovation journey. It identifies additional success factors and discusses opportunities to improve the relation of SNM literature with other seminal fields.

Government seed money is important in providing a breakthrough in enterprise network initiatives. A focus on architectural innovation instead of technology innovation is to be preferred for stimulating integrated design concepts.

The paper addresses the relevance and limitations of SNM success factors during the formation of enterprise networks. The study shows how an integrated design approach was used to cluster innovation opportunities and to inspire innovation development and collaboration for know-how development between multiple players.

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.

The purpose of this paper is to investigate the commercial aspect of “green” building construction and whether increased investment costs are profitable taking the reduction in operating costs into account. The investment viability is approached by comparing investment in conventional and “green” residential building, particularly passive houses, using real construction and post‐occupancy conditions.

The key data were obtained by surveys and personal interviews. The first survey was directed to the companies which had experience of building low‐energy housing and the second survey to housing companies that actively manage operation of low‐energy houses.

Findings indicate that low‐energy buildings are considered an interesting and sound business opportunity, and investment analysis indicates that low‐energy houses (particularly passive houses) can be more attractive investments than conventional residential buildings. The long‐term strategy of building low‐energy buildings can give competitive advantages. The government initiative and the construction regulations are found to be necessary in eliminating the initial barrier to energy‐efficient projects and achieving long‐term environmental goals.

This paper provides insights into the investment decisions and contributes to the understanding of the construction, operation and profitability of energy‐efficient residential buildings.

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.

The use of fossil fuels in developing countries places increasing economic, health, and environmental costs on the population. In decentralized and rural communities without existing grid systems, direct solar technologies provide the basis for electricity production, for water pumping and hot water, and for heating of houses. Examples and case studies for each of these direct solar technologies are presented which may be directly applicable or potentially modified for rural development in countries such as Uzbekistan and Turkmenistan, which have ample direct solar resources. Related design involving both daylighting and passive cooling are described as part of the incorporation of passive solar heating techniques.

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 purpose of this study is to quantify the energy heating performance of apartment buildings in Kosovo built after 2003 and compare it against the energy heating performance of buildings in member states of EU and selected European countries.

This paper takes a case study approach focussed on the assessment of the heating energy performance of the building. This approach facilitated a detailed calculation of the selected materials’ energy performance used in a representative building structure in Kosovo comparing with passive buildings standard and energy heating performance of buildings in member states of EU and selected European countries.

Results of quantitative research find that the energy heating performance of apartment buildings in Kosovo built after 2003 is far higher than that of passive buildings standard and is better than the average annual energy heating performance of apartment buildings in member states of the EU and selected European countries.

The research provides new knowledge regarding energy heating performance in new residential buildings in Kosovo and compares the findings with earlier research and energy consumption in other selected European countries. The research provides great benefits for researchers and practitioners working in the field of energy management as it compares the energy performance of residential buildings across Europe.

This paper provides a perspective on investigating the energy performance of a building structure of a residential apartment building in Prishtina, Kosovo. By unveiling the level of energy consumption of a residential apartment building in Kosovo representative of the new construction period can help the facility managers to acknowledge the standards they must achieve to refurbish the old building stock to achieve at least the same standard as the buildings in the new construction period.