Relevant bibliographies by topics / Double-skin facade

Academic literature on the topic 'Double-skin facade'

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Published: 4 June 2021
Last updated: 22 February 2023

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Journal articles on the topic "Double-skin facade"

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Cao, Xi, Katsuhiko Nawa, Baoyin Song, Ryo Aonuma, and Naoki Kurosawa. "The Solar Heat Cutting Performance of Double-Skin Facades." European Journal of Engineering and Technology Research 7, no. 3 (May 16, 2022): 25–29. http://dx.doi.org/10.24018/ejeng.2022.7.3.2809.

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The solar heat cutting performance of double-skin facades was analyzed in this paper. A physical model was built to calculate the thermal characteristics of double-skin facades. The effects of location, floor height, facade facing direction, blind slice angle, and skin style on solar heat cutting were investigated. The results show that double-skin facades can effectively cut the heat flux entering room, especially for west facing facade. Comparing with the single-skin facade, the double-skin facade cuts 1410.2 Wh/m2 more heat to enter room for west facing facade in a clear summer day in Nagano, Japan. Floor height mainly influences the outlet air temperature of the facade intermediate space, but not the heat fluxes. Locations somewhat affect the solar fluxes on outer facade surface.
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Gelesz, A., and A. Reith. "Classification and re-evaluation of double-skin facades." International Review of Applied Sciences and Engineering 2, no. 2 (December 1, 2011): 129–36. http://dx.doi.org/10.1556/irase.2.2011.2.9.

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Abstract The construction of double-skin glass facades in Hungary has mainly design or acoustic motivations. The potential energy savings or risks of double-skin facades are, however, not commonly evident. This fact is not surprising if we notice that there is no widely excepted classification of these constructions. In the following article different facade typologies are compared (Pottgiesser, BBRI, Széll) and an attempt to develop a transparent classification system is made. Subsequently a few chosen facade types, which are expected to perform well in the Hungarian climate, are evaluated through computer simulation programs to serve as a guideline for the design on climates similar to the domestic one.
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Andreeva, Darya, Darya Nemova, and Evgeny Kotov. "Multi-Skin Adaptive Ventilated Facade: A Review." Energies 15, no. 9 (May 9, 2022): 3447. http://dx.doi.org/10.3390/en15093447.

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Multi-skin ventilated facades with integrated building elements that respond to climatic conditions (mechanized openings and automatic shading with intelligent control) present the potential of improving overall annual energy savings by adapting the thermal properties of buildings. This paper presents a literature review on multi-skin adaptive ventilated facades. Additionally, this article presents a literature review on building envelopes that contain inner-air layers. The operation modes of the air layer used in building enclosure structures are classified and summarized and the thermal performance and benefits of climate-adaptive facades are discussed and reviewed. The existing operation modes of the air layer used in building envelopes are summarized, outlined and roughly classified into the following types: the enclosed type, the naturally ventilated type and the mechanically ventilated type. One of the sustainable development trends is the investigation and application of energy-efficient climate-adaptive facades. In this study, the energy modeling of a high-rise office building was calculated using the Green Building Studio. The annual energy, the annual CO2 emissions, and life cycle energy for the following three types of facade were estimated: a single-layer facade made of three-layer glass with argon, a double ventilated facade, and a triple ventilated facade with a double chamber. The calculation results show that the annual energy of the building with an adaptive triple-skin facade could be reduced by 15% compared with buildings with a single skin facade.
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Palko, Milan. "Program for Quantification Temperature and Aerodynamic Mode of Double-Skin Facade." Advanced Materials Research 855 (December 2013): 102–7. http://dx.doi.org/10.4028/www.scientific.net/amr.855.102.

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Program functional diagram. Dimensional and physical quantification of individual parts of double-skin facade. Reference year for Bratislava. Direct normal solar radiation, diffuse solar radiation and its transformation to required surface. Mass flow rate designation by intermediate space of double-skin facade by means of iteration method. Mode of double transparent facades from natural convection for day or night. Mode at wind effect. Conditions for designation of algorithm suitability for specific moment.
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Penić, Milja, Nikolay Vatin, and Vera Murgul. "Double Skin Facades in Energy Efficient Design." Applied Mechanics and Materials 680 (October 2014): 534–38. http://dx.doi.org/10.4028/www.scientific.net/amm.680.534.

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Double skin facade is one of the possible approaches to bioclimatic design. Bright architectural expression is combined with lots of potential natural heating and ventilation of the internal space of buildings. Double skin facade considered as an element of building heating, ventilation, or, finally, as an element of conditioning in the building. The article provides a classification of Double skin facade, analyzes the advantages and disadvantages Double skin facade.
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Ghonimi, Islam. "Assessing Daylight Performance of Single vs. Double Skin Façade in Educational Buildings: A Comparative Analysis of Two Case Studies." Journal of Sustainable Development 10, no. 3 (May 31, 2017): 133. http://dx.doi.org/10.5539/jsd.v10n3p133.

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The bulk of research on the performance of double skin facade is carried out in moderate climate with concern to ventilation and thermal performance. This research concerns day-light performance of double skin facades in hot arid zones, in Educational Buildings. This investigation adopts an inductive method using comparative analytical approach to convert general intuitions on the daylight performance of a double skin facade, in hot arid areas, into the grounds of understanding its performance based on research.Based on two case studies of lecture halls; the first with Single Skin Façade (SSF) and the second with Double Skin Façade (DSF); the impact of double skin façade on lighting performance is examined. The Protocol was applied to south facing models under overcast sky conditions to test significant effects of double skin façade on illumance values inside the lecture halls. Simulation results indicate that a double skin facade can achieve high lighting performance with better energy savings than a single skin façade; also the basic characteristics of width and distance of two walls are examined. It was expected that DSF fail to meet the acceptable standard indoor illuminance requirement of 200 to 300 lux. Comparing the single and double skin facade, the area percentage of the lecture hall, which covered with acceptable illumination level of 200 to 300 lux, are found in range of 10%, 50% respectively. In addition, the area percentage of the lecture hall, which covered with acceptable illumination level of 100 to 300 lux, is found in range of 30%, 80% respectively.
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Palko, Milan, and Adela Palková. "Selected Aerodynamic Problems of Double Skin Facade." Advanced Materials Research 1057 (October 2014): 137–44. http://dx.doi.org/10.4028/www.scientific.net/amr.1057.137.

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Simulation program ANSYS. For mathematical description of fluid flow (air, liquid), mathematic variation methods are used represented by the two most significant ones: Finite Element Method (FEM) and Volume Element Method (VEM). The fluid flow problem is defined by three laws: conservation of mass, conservation of momentum, conservation of energy. Geometrical parameters of element FLUID 141. Aerodynamic mode of double skin façade. Simulation model for inlet and outlet channel of double skin façade. To estimate aerodynamic entrances for inlet and outlet channel of the intermediate space for double skin facades. Aerodynamic and geometrical boundary conditions of the model. Simplified modelling of net for insect with support of real constant.
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Sung, Uk-Joo, and Seok-Hyun Kim. "A Study on the Improvement of Double-Skin Facade Operation for Reducing Heating Load in Winter." Sustainability 11, no. 22 (November 7, 2019): 6238. http://dx.doi.org/10.3390/su11226238.

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A double-skin facade makes it possible to gain irradiance through the glass on the outer side in summer, and to increase the temperature of air flowing in the cavity so as to induce the flow of air current. Therefore, a double-skin facade is able to reduce the load of the outer skin, which is delivered from the outside to the inside in summer, and to serve as a buffer space for the internal and external environments in winter, and thereby prevent heat loss from the building envelope. Theoretical analysis was conducted to review the heat effects of a double-skin facade and to evaluate the performance of a plan for indoor load reduction. This study carried out a field measurement of a building with a double-skin facade and then analyzed the thermal phenomenon occurring in between the outer skin of the outside and the skin of the inside facing the building surface, according to the effects of irradiance going into the double-skin facade cavity. In order to propose an indoor air conditioning energy reduction plan using preheated air through the double-skin facade, this study utilized a building simulation to be implemented on the target building and then analyzed the effects of the improvement plan for the double-skin facade. A simulation model was suggested that implemented the aforementioned airflow network and analyzed the ventilation performance and energy performance according to the application of alternative plans and thermal effect. To find the actual state of operation of the double-skin facade in winter, this study measured the target building. A solar chimney-based double-skin facade was analyzed in winter. As a result, with the application of a solar chimney and a rise in its height, the available capacity of relatively larger solar heat increased, and therefore the proposed plan had excellent performance in terms of heating energy saving. When the thermal effect was applied to the solar chimney, the heating energy use effect of the solar irradiance of the double-skin facade was larger. When thermal effect was applied to a three-floor solar chimney, the heating energy use increased to about 7.6 times higher than that of the original performance of the double-skin facade.
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Feng, Xin, Hua Yang, Xi Yang Feng, Feng Yun Jin, and Guo Qiang Xia. "A Review of Research Development of Ventilated Double-Skin Facade." Applied Mechanics and Materials 587-589 (July 2014): 709–13. http://dx.doi.org/10.4028/www.scientific.net/amm.587-589.709.

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Demands for the building energy conservation, thermal and visual comfort make the ventilated double-skin facade (DSF) more attractive and more popular in commercial buildings. This paper reviews the recent research development of ventilated double-skin facade in China. The velocity and temperature distribution in the double-skin facade (DSF) are reviewed, together with the effects of glass types, channel width, intensity of solar radiation and shading methods on the heat transfer of ventilated double-skin facade (DSF). This paper also describes the effect of the different combinations of glass, blinds settings, ventilation rate and the channel width, intensity of solar radiation and shading. Furthermore, the methods to improve the energy saving of ventilated double-skin facade (DSF) are also reviewed.
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Maknun, Johar. "APPLICATION OF THE DOUBLE SKIN FACADE CONCEPT IN AN EFFORT TO INCREASE THE THERMAL COMFORT OF IMAGE STUDIO ROOM." Journal of Architectural Research and Education 2, no. 1 (May 1, 2020): 90. http://dx.doi.org/10.17509/jare.v2i1.24128.

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Abstrak- The development of technology in buildings is one of the factors triggering the acceleration of methods in the facade configuration system. Double Skin Facade (DSF) is one of the building facade concept innovations. The purpose of applying the DSF concept is to optimize the use of energy related to the air conditioning system to obtain thermal comfort in buildings. The results of measurements of the existing condition of the Image Studio room in the morning until 11.00 are included in the optimal comfort category, 11.00 - 13.00 are in the warm comfortable category and starting at 13.00-18.00 tend not to meet thermal comfort. Based on the simulation results the use of Double Skin Facade can reduce the temperature in the room around 3.47oC. With the application of Double Skin Facade in this Image Studio room, it can reduce the heat radiation from sunlight that directly enters through the window because it can be detained first in the double facade. The application of Double Skin Facade can increase the thermal comfort of an Image Studio room. Kata kunci- Double Skin Façade, Thermal Comfort
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Dissertations / Theses on the topic "Double-skin facade"

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Yellamraju, Vijaya. "Evaluation and design of double-skin facades for office buildings in hot climates." Thesis, Texas A&M University, 2003. http://hdl.handle.net/1969.1/205.

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The main objectives of this research are (a) to investigate the thermal effect of double skin facades in office buildings in hot climates and (b) to propose guidelines for their efficient design based on this evaluation. The study involves the energy performance analysis of two buildings in India. A base case with the existing building skin was simulated for both the cities. The main source for the high cooling loads was found to be heat gain through windows and walls. This led to the evolution of a series of facade strategies with the goals of reducing heat gain, providing ventilation and day-lighting. The buildings were then simulated for their energy performance with the proposed double-skin strategies. Each of these strategies was varied according to the layers constituting the facade, the transparency of the facade and the orientation of the facade to which it is applied. Final comparisons of energy consumption were made between the proposed options and the base case to find the most efficient strategy and also the factors that affected this efficiency. The simulations were done using the building simulation software, Ener-Win. The double skin was simulated as per an approximate and simplistic calculation of the u-value, solar heat gain coefficient and transmissivity properties of the layers constituting the facade. The model relied on logically arrived at assumptions about the facade properties that were approximately within 10% range of measured values. Based on inferences drawn from these simulations, a set of design guidelines comprised of goals and parameters was generated for design of double-skin facades in hot climates typical to most of the Indian subcontinent. It was realized that the double-skin defined typically as a 'pair of glass skins separated by an air corridor' may not be an entirely energy efficient design strategy for hot climates. However, when used appropriately in combination with other materials, in the right orientation and with the right transparency, a double-layered facade turns out to be an energy efficient solution.
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Altahlawi, Naif Tarik. "Integrated Thermal and Daylight Performance Comparison of Single and Double Glass Skin Facade for Hot Climate Conditions." Diss., Virginia Tech, 2019. http://hdl.handle.net/10919/90783.

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Visual integration of the building interior and exterior is one of the charms of today's architecture. The Double-Skin facade system is a technology that can reduce the drawbacks of using glass in a building's elevation. In fact, the double-skin façade (DSF) offers transparency while reducing energy consumption when compared to single-skin systems in cold and moderate weather conditions. However, there is no clear evidence of how the system will perform in hot climate conditions. In this research, a testing procedure was established to experimentally evaluate the performance of the double-skin façade system, data was collected to create multiple regression models, and then evaluate the double-skin façade's performance and compare it to a single-skin system in hot arid climate conditions.
Doctor of Philosophy
Improving the quality of indoor environments is a main goal in today’s architecture. Towards this goal, the use of glass and curtain walls is common in office buildings. The building façade is a key factor for the amount of energy consumed to reach comfort levels in the building. That is, because facades influence lighting, glare, heat gain, noise safety and energy usage. Therefore, the use of glass improves transparency which can interfere with comfort levels inside the building due to solar heat gain. The Double Skin façade system is widely adopted in Europe and has been shown to reduce energy used for heating in cold weather. In winter, heat losses can be reduced as the system’s intermediate cavity acts as a thermal buffer. However, there is no clear understanding of how the system will perform in hot arid climate conditions where cooling is the dominant operating mode. A Double Skin Façade can provide shading during the overheating period, while having the desired glass elevations sought by designers. This is due to ventilation and solar control devices located inside the system’s cavity. Being placed between the interior and the exterior glass panels, solar control devices are protected from the weather, which in return decreases its size. Furthermore, the additional glass panel allows windows in the system’s inner layer to be opened for natural ventilation. Unfortunately, the performance of the Double Skin Façade system for hot arid climate is not well documented. Therefore, the primary goal of this research is to compare the thermal and light performance of the Double Skin Façade system to a single façade system for hot weather conditions.
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Pappas, Alexandra (Aleka). "Energy modeling of a double skin facade: A method using CFD and EnergyPlus." Diss., Connect to online resource, 2006. http://gateway.proquest.com/openurl?url_ver=Z39.88-2004&rft_val_fmt=info:ofi/fmt:kev:mtx:dissertation&res_dat=xri:pqdiss&rft_dat=xri:pqdiss:1433484.

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Zhang, Rui. "Smart Buildings| An Integrative Double Skin Facade Damper System for Safety and Energy Efficiency." Thesis, University of New Hampshire, 2018. http://pqdtopen.proquest.com/#viewpdf?dispub=10688477.

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A smart building is an intelligent living space that elevates energy efficiency, comfort and safety. The word “smart” implies that the building would have a decision making system that can sense its conditions and reacts to them in an automatic and effective manner. Modem buildings contain many subsystems and, thus, to achieve automation, sophisticated sensing networks and robust control systems must be installed. The proposed research focuses on integrating several building systems—structural health monitoring (SHM), and structural and environmental controls—and explores synergy among them to improve efficiency and sustainability of buildings.

More specifically, an integrative, smart building system is developed by combining double skin façades and mass dampers in buildings to improve both safety and energy efficiency. Double skin façade systems protect and insulate buildings with two heavy glass layers between which air is allowed to flow for ventilation. By enabling movements in the outer façade skin, the façade can be used as a mass damper that reduces structural vibration and damage during earthquakes and wind storms. The added mobility also leads to innovative ways to control ventilation rate and improve energy efficiency by adjusting the gap size between the outer and inner skins.

In this dissertation research, the energy impact of the integrated system was first investigated. Then both passive and active structural control strategies were experimented and analyzed on a six-story shear building model. Results indicated the proposed system can significantly reduce structural response under the earthquakes excitations. In addition, the sensor networks and actuators introduced by the active structural control system were utilized for structural health monitoring purposes. The actuators provided harmonic excitations while the acceleration data were collected by the sensor networks to perform damage diagnosis.

Finally, since typical SHM systems require large networks of sensors that are costly to install, this dissertation research also examined using smartphones as alternative sensors. Using the aforementioned six-story experimental structure, a sensing system consisted of six smartphones was tested and proven effective in detecting structural damage. The experimental result demonstrates that further developments of smartphone SHM can lead to cost-effective and quick sensor deployments.

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Wong, Pow Chew James Built Environment Faculty of Built Environment UNSW. "Natural ventilation in double-skin fa??ade design for office buildings in hot and humid climate." Publisher:University of New South Wales. Built Environment, 2008. http://handle.unsw.edu.au/1959.4/41014.

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This research seeks to find a design solution for reducing the energy usage in high-rise office buildings in Singapore. There are numerous methods and techniques that could be employed to achieve the purpose of designing energy efficient buildings. The Thesis explores the viability of double-skin fa??ades (DSF) to provide natural ventilation as an energy efficient solution for office buildings in hot and humid environment by using computational fluid dynamic (CFD) simulations and case study methodologies. CFD simulations were used to examine various types of DSF used in office buildings and the behaviour of airflow and thermal transfer through the DSF; the internal thermal comfort levels of each office spaces were analyzed and compared; and an optimization methodology was developed to explore the best DSF configuration to be used in high-rise office buildings in the tropics. The correlation between the fa??ade configurations, the thermal comfort parameters, and the internal office space energy consumption through the DSF is studied and presented. The research outcome of the Thesis has found that significant energy saving is possible if natural ventilation strategies could be exploited with the use of DSF. A prototype DSF configuration which will be best suited for the tropical environment in terms of its energy efficiency through cross ventilation strategy is proposed in this Thesis. A series of comprehensive and user-friendly nomograms for design optimization in selecting the most appropriate double-skin fa??ade configurations with considerations of various orientations for the use in high-rise office buildings in the tropics were also presented.
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Matour, Soha. "A new design for double skin facade in warm climates: Improving thermal performance and natural ventilation of the system." Thesis, Queensland University of Technology, 2022. https://eprints.qut.edu.au/231909/1/Soha_Matour_Thesis.pdf.

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This thesis contributes to the improvement of Double Skin facades' thermal performance in warm climates. A new design for DSF was proposed and evaluated using an experimental study on a scaled model and Computational Fluid Dynamics simulations. The proposed facade named IS-DSF (Interstitial slat-blind DSF) showed the capability to reduce overheating risk in the cavity due to two applied strategies: shading devices’ specific placement and wind-induced ventilation improvement. Finally, a framework was developed for the implementation of IS-DSF in warm climates applicable at the early stage of building design.
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Velázquez, Romo Ernesto. "Processus de conception énergétique de bâtiments durables." Thesis, Paris, ENSAM, 2015. http://www.theses.fr/2015ENAM0022/document.

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L'objectif de ce travail de thèse est de développer une méthodologie d'aide à la prise de décisions pour la conception énergétique de bâtiments durables. La méthodologie proposée est composée de : (1) une base de seize indicateurs caractérisant la performance énergétique du bâtiment, couvrant les trois dimensions du concept de la durabilité (aspects environnementaux, économiques et de confort des occupants) et suivant une approche de type cycle de vie ; (2) une méthode d'évaluation de ces indicateurs adaptée au niveau de précision de la connaissance du bâtiment dans les premières phases de projet ; (3) une logique de progression des décisions de conception donnée comme un modèle de répartition séquentielle des choix à effectuer à chaque phase de projet ; et (4) une base de connaissances d'éléments du bâtiment comprenant les données techniques, environnementales et économiques nécessaires pour la méthode d'évaluation. Cette méthodologie est destinée à être utilisée par la maîtrise d'œuvre d'un projet de construction, y compris architectes et bureaux d'études concernés par la performance énergétique, pour la conception de bâtiments de bureaux dans un contexte français. Un outil numérique d'évaluation a été mis en place comme une première application de la méthodologie proposée afin d'étudier ce qu'elle peut apporter au concepteur comme éléments d'aide à la prise de décisions. L'intérêt de la mise en œuvre de la méthodologie a été validé par divers cas d'étude à chaque stade du processus de conception : de la phase d'Esquisse à la phase d'Avant-Projet Détaillé. En particulier, l'intégration d'une façade double peau vitrée, dont l'impact sur la performance du bâtiment est encore peu maîtrisé, a été évaluée
The aim of this thesis work is the development of a decision-support methodology for the energy design of sustainable buildings. The proposed methodology consists of: (1) a set of sixteen indicators of energy performance, covering the three dimensions of the concept of sustainability (environmental, economic and user comfort aspects) and based on a whole life-cycle approach; (2) a framework for the calculation of these indicators, adapted to the level of knowledge and detail of buildings in the early design phases; (3) a decision making roadmap, proposed as a sequential model for structuring decision making throughout the design process; and (4) a knowledge base of building elements, compiling the necessary technical, environmental and economic data for evaluating energy performance. This methodology is aimed to assist architects and engineers who participate in the energy design of office buildings within a French context. An assessment tool has been developed as a first application of the proposed methodology in order to determine its contribution to the process of decision making. The methodology has been validated through various case studies at each stage of the design process: from the schematic design phase to the detailed design phase. In particular, the integration of a double skin facade, whose impact on building performance is still not fully understood, was assessed
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Michna, Patrik. "Polyfunkční dům." Master's thesis, Vysoké učení technické v Brně. Fakulta stavební, 2017. http://www.nusl.cz/ntk/nusl-265393.

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The assignment of my diploma thesis was to design a polyfunctional building. Function of the building is based on the requirements of the Land Use Plan Brno, cadastral zone Židenice. The aim of the design was to improve the quality of public space in the area by creating parks, urban parterre with services, parking and by bringing missing features to the area. The building is located in the centre of the plot. The main facade is oriented to the main street. Design creates new parking on the ground and in the underground garage. On the first floor are rentable spaces for commerce and services. At 2nd and 3rd floor are open space offices with the possibility of spatial variability solutions. Architectural expression of the building is simple, consisting as a compact mass with parterre subsided, useful in terms of energetical sustainability. The facade of the building is made as a combination of a transparent double skin facade and opaque ventilated facade with fibre cement panels. Structural system is a precast concrete frame with a cast-in-place reinforced concrete shear core. Foundation is made as a reinforced concrete pads and strips. Ceiling is made of a precast prestressed hollow core slabs.
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Zoubir, Amine. "Etude des transferts thermo-convectifs dans un canal semi-ouvert : Application aux façades type double-peau." Thesis, Lyon, INSA, 2014. http://www.theses.fr/2014ISAL0003/document.

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Notre investigation porte sur la simulation numérique des échanges thermo-convectifs dans un canal vertical ouvert à flux imposé. Cette étude rentre dans le cadre des recherches sur le rafraîchissement passif des composants PV intégrés au bâtiment. À cet effet, un code numérique en Différences Finies est utilisé pour résoudre les équations de Navier-Stokes et simuler la convection naturelle dans un canal. Ce problème reste difficile à résoudre parce que l'écriture des conditions aux limites d'entrée et de sortie reste un problème ouvert. Notre travail consiste d'abord en étude des différentes conditions aux limites pour le benchmark numérique AMETH. Les travaux réalisés ont permis de faire un premier choix sur les conditions aux limites. L'étude s'oriente ensuite sur la qualification et la quantification numériques et expérimentales pour deux fluides : l'air (convection-rayonnement) et l'eau (convection pure). Les résultats numériques/expérimentaux ont été comparés et les discordances ont été analysées. Plusieurs aspects phénoménologiques (rayonnement entre surfaces, variation des propriétés thermo-physiques, variation du nombre de Prandtl) ont été abordés afin de caractériser leurs influences respectives sur l'écoulement et le transfert thermique. Enfin, dans le but d'apporter des éléments de réponses sur les conditions aux limites dynamiques, nous avons simulé la convection naturelle d'un canal dans une cavité et tenté une modélisation
The present investigation deals with natural convection flow in a vertical open-ended channel with wall constant heat flux. This study falls under the framework of research on passive cooling of building integrated PV components. For this purpose, a numerical code developed with Finite Differences scheme is used to solve Navier-Stokes equations and simulate the natural convection in a channel. This problem is difficult to solve because the writing of inlet/outlet boundary conditions remains an open problem. First, our work consists of studying different boundary conditions for the the numerical benchmark AMETH. The work carried out has enabled a first choice of boundary conditions. The study then focuses on numerical and experimental quantification and qualification for two fluids : air ( convection - radiation) and water ( pure convection) . Experimental and numerical results were compared and discrepancies were analyzed. Several phenomenological aspects ( surface radiation, thermophysical properties variation, Prandtl number variation ) were discussed in order to characterize their influence on flow and heat transfer. Finally, in order to provide some answers on dynamical boundary conditions, we simulated natural convection of a channel inside a cavity and tried a modeling
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Haase, Matthias. "Double-skin facades for Hong Kong." Thesis, Click to view the E-thesis via HKUTO, 2008. http://sunzi.lib.hku.hk/hkuto/record/B41896993.

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Books on the topic "Double-skin facade"

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Min, Li. Double skin façades: An environmental and energy review. London: University of East London, 2001.

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Eberhard, Oesterle, ed. Double-skin facades: Integrated planning : building physics, construction, aerophysics, air-conditioning, economic viability. Munich: Prestel, 2001.

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Bonham, Mary Benedict. Bioclimatic Double-Skin Facades. Taylor & Francis Group, 2019.

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Bioclimatic Double-Skin Facades. Taylor & Francis Group, 2019.

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Bonham, Mary Ben. Bioclimatic Double-Skin Façades. Taylor & Francis Group, 2019.

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Bonham, Mary Ben. Bioclimatic Double-Skin Façades. Taylor & Francis Group, 2019.

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Bonham, Mary Ben. Bioclimatic Double-Skin Façades. Taylor & Francis Group, 2019.

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Bonham, Mary Ben. Bioclimatic Double-Skin Façades. Taylor & Francis Group, 2019.

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Eberhard, Oesterle, ed. Double-skin facades: Integrated planning. Munich: Prestel, 2001.

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Oesterle, Eberhard. Double-Skin Facades: Integrated Planning (Architecture). Prestel Publishing, 2001.

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Book chapters on the topic "Double-skin facade"

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Zhang, Weijie, Yanyan Li, Dongyuan Gao, and Qianqian Zhao. "Research on Built Environmental Characteristics of Double-Skin Facade." In Lecture Notes in Electrical Engineering, 435–51. Berlin, Heidelberg: Springer Berlin Heidelberg, 2013. http://dx.doi.org/10.1007/978-3-642-39578-9_47.

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Le, Sha, Youming Chen, Yuan Bi, and Xiang Lu. "Modeling and Simulation of Ventilated Double-Skin Facade Using EnergyPlus." In Lecture Notes in Electrical Engineering, 241–52. Berlin, Heidelberg: Springer Berlin Heidelberg, 2013. http://dx.doi.org/10.1007/978-3-642-39578-9_26.

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Tkachuk, Angelina, Elina Umerenkova, Andrey Goikalov, and Mikhail Novikov. "Two-Dimensional Temperature Fields of Variants Design of a Double-Skin Facade Structure." In Lecture Notes in Civil Engineering, 255–69. Cham: Springer International Publishing, 2022. http://dx.doi.org/10.1007/978-3-031-12703-8_25.

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Shao, Jingjing, Siegfried K. Yeboah, Tiesheng Zhu, and Yilin Li. "Simulation Study on the Spreading of Fire-Induced Smoke in Natural-Ventilated Double-Skin Facade Buildings." In Environmental Science and Engineering, 1011–18. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-13-9528-4_102.

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Yang, Hua, Xiyang Feng, Guoqiang Xia, and Qianzhao Wan. "Experimental Study on Impact of Ventilated Double-Skin Facade on the Indoor Thermal Environment in Winter." In Lecture Notes in Electrical Engineering, 523–31. Berlin, Heidelberg: Springer Berlin Heidelberg, 2013. http://dx.doi.org/10.1007/978-3-642-39584-0_59.

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Alemdağ, Esra Lakot, and Figen Beyhan. "Energy Saving with Double-Skin Glazed Facades in Multistorey Buildings." In Progress in Exergy, Energy, and the Environment, 533–40. Cham: Springer International Publishing, 2014. http://dx.doi.org/10.1007/978-3-319-04681-5_49.

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Cetiner, I., and M. Aygun. "Investigating the Energy Efficiency of Double-Skin Glass Facades for an Office Building in Istanbul." In Smart & Sustainable Built Environments, 103–10. Oxford, UK: Blackwell Publishing Ltd, 2008. http://dx.doi.org/10.1002/9780470759493.ch10.

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D’Agostino, Pierpaolo, and Federico Minelli. "Robustness Assessment of a Low Poly Modeling Strategy for Performance Simulation of Double-Skin Green Facades." In Advances in Intelligent Systems and Computing, 615–25. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-63403-2_55.

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Bonham, Mary Ben. "Defining the Double-Skin Facade in the Postwar Era." In Constructing Building Enclosures, 228–46. Routledge, 2020. http://dx.doi.org/10.4324/9780429296963-15.

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Stec, W. J., and A. H. C. van Paassen. "Validation of the simulation models of the double skin facade." In Advances in Building Technology, 1181–88. Elsevier, 2002. http://dx.doi.org/10.1016/b978-008044100-9/50147-9.

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Conference papers on the topic "Double-skin facade"

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Hollingsbee, Tai, John Kooymans, and Terry McDonnell. "Designing the Right Double Skin Facade." In Structures Congress 2009. Reston, VA: American Society of Civil Engineers, 2009. http://dx.doi.org/10.1061/41031(341)277.

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Dama, Alessandro, Jaime Varas del Ser, Ettore Zanetti, Francesco Casella, and Olena Kalyanova Larsen. "Modelling naturally ventilated double skin facade in Modelica." In 2021 Building Simulation Conference. KU Leuven, 2021. http://dx.doi.org/10.26868/25222708.2021.30335.

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AZARBAYJANI, Mona. "Climatic Based Consideration Of Double Skin Facade System: Natural Ventilation Performance Of A Case Study With Double Skin Facade In Mediterranean Climate." In 2017 Building Simulation Conference. IBPSA, 2013. http://dx.doi.org/10.26868/25222708.2013.2181.

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Tingqiao, Ye, and Ke Xiufang. "Study on Thermal Performance of Passive Evaporative Cooling Double-Skin Facade." In 2011 International Conference on Measuring Technology and Mechatronics Automation (ICMTMA). IEEE, 2011. http://dx.doi.org/10.1109/icmtma.2011.719.

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Xingtian, Xu, and Chen Xi. "Elite bias genetic algorithm for optimal control of double-skin facade." In 2015 IEEE Congress on Evolutionary Computation (CEC). IEEE, 2015. http://dx.doi.org/10.1109/cec.2015.7257310.

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Zhang, Yangwen, Wulf Wulff, Achim Bleicher, Laurenz Wernicke, Thomas Schauer, and Michael Engelmann. "Moveable Facade Elements for Sustainable High-rise Buildings." In IABSE Congress, Nanjing 2022: Bridges and Structures: Connection, Integration and Harmonisation. Zurich, Switzerland: International Association for Bridge and Structural Engineering (IABSE), 2022. http://dx.doi.org/10.2749/nanjing.2022.1046.

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Abstract:
<p>This paper presents a sustainable semi-active distributed-Multiple Tuned Facade Damping (d-MTFD) system that utilizes the existing mass of the Double-Skin Facade's outer skin as damping mass to mitigate structural vibrations caused by wind excitation. Based on this concept, a prototype with one full-scale parallel moveable facade element has been developed, built, and validated. A stepper motor working together with its connected energy harvesting circuit is innovatively applied as an adjustable electrical damper and simultaneously as an energy harvester. Its feasibility has been proven through experiments using Hardware-in-the-Loop (HiL) simulations. An energy harvesting efficiency of 75% was achieved by using a two-stage power converter as the energy harvesting circuit. The self-sufficiency of the semi-active d-MTFD system was achieved.</p>
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Joe, Jae-Wan, Won-Jun Choi, Jung-Ho Huh, and Seung-Chul Shin. "Cooling Load Reduction of Office Buildings Integrated with a Multistory Double-Skin Facade." In ISES Solar World Congress 2011. Freiburg, Germany: International Solar Energy Society, 2011. http://dx.doi.org/10.18086/swc.2011.17.18.

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Tkachenko, Oksana A., Victoria Timchenko, Guan Heng Yeoh, John A. Reizes, and Graham de Vahl Davis. "THREE-DIMENSIONAL STUDY OF NATURAL CONVECTION IN COMBINED DOUBLE-SKIN FACADE/ROOF CONFIGURATION." In Proceedings of CHT-15. 6th International Symposium on ADVANCES IN COMPUTATIONAL HEAT TRANSFER , May 25-29, 2015, Rutgers University, New Brunswick, NJ, USA. Connecticut: Begellhouse, 2015. http://dx.doi.org/10.1615/ichmt.2015.intsympadvcomputheattransf.600.

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Chen, Jwohua, Yun-Lian Chern, and Mingchin Ho. "Wind Pressures Distribution on Porous Exterior Walls of Buildings Double Skin facade System." In International Symposium on Mechanical Engineering and Material Science (ISMEMS 2017). Paris, France: Atlantis Press, 2018. http://dx.doi.org/10.2991/ismems-17.2018.15.

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Sungkono, Wiratama Dhaneswara, Jeri At Thabari, Koza Brajamagenta, and Yulianto Sulistyo Nugroho. "Modeling of fire spread control in double skin facade by using water spray systems." In THE 5TH INTERNATIONAL TROPICAL RENEWABLE ENERGY CONFERENCE (THE 5TH iTREC). AIP Publishing, 2021. http://dx.doi.org/10.1063/5.0063934.

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