Socio-environmental Framework for Integration of Thermal Mass Windcatchers with Lightweight Tensile Structures in Contemporary Hot-Arid Urban Context of Tehran

Mirhosseiniardakani, Homeiraalsadat, Mirhosseiniardakani, Homeiraalsadat

January 2016

The integration of windcatchers in the urban context of hot-arid context of Tehran needs to address two changes in the current utilization: 1) high density context which makes it harder to access to sufficient airflow in the urban context, and 2) sociocultural shifts towards dependencies on modern mechanical air-conditioning systems. Windcatchers are unique tools existing in the hot-arid regions in the Middle East. Windcatcher uses thermal mass, evaporation techniques, and stack effect to deliver human comfort to the residents of the building. Vernacular windcatchers are useful for moderating the indoor air temperature. Yet, using natural ventilation techniques as passive strategies are outdated in recent decades and there are a couple of reasons for that such as maintenance difficulties, lack of urban air filtration methods, decline of cooling efficiency due to modified airflow patterns, habitable space utilization modifications, and dependencies on mechanical cooling systems. On the other hand, tensile structures have the potential to be considered as a tool to upgrade the windcatchers and use them in the modern urban context which will also help reducing energy and reviving local textile industry. This research tries to propose a method that emphasizes on the adaptability of windcatchers and tensile structures, inhabitant control, airflow control and reuse of heavy thermal mass. Also, the proposed model offers improvements for environmental performance of lightweight textiles, such as particulate matter filtration, kinetic energy transformation, and photoresponse for passive shading or natural daylighting strategies. The main goal of this research is to define the parameters required to enhance inhabitant adaptability with the windcatcher and also natural ventilation cooling system. In this research, important characteristics of Sangelaj neighborhood in Tehran are considered such as existing windcatcher dimensions, micro-climate conditions, and urban morphology. Then, different methods are proposed to develop the heat transfer and airflow analysis of the integration between windcatchers and tensile structures. The research suggests methods for adaptation of windcatchers in existing buildings of Tehran using tensile structures. It also proposes methods for the new buildings in the urban context of Sangelaj neighborhood in Tehran.

climate responsive architecture

integration

windcatcher

adaptable design

Exploring Ultraviolet B Radiation in the Landscape

Cox, Victoria S.K.

18 April 2013

Ultraviolet B (UVB) radiation from the sun is the chief cause of skin cancer and is also involved in the development of Vitamin D in humans. This poses an interesting challenge, especially for people living in locations at mid to high latitudes. Through an integrative research review and controlled testing the amount of UVB humans receive in the landscape has been explored. Two existing computer models along with personal dosimeter badges were used to evaluate how much UVB students at a school in Waterloo, Ontario received under various conditions in February, 2013. Results showed that it is possible to get the equivalent of 1000 I.U. of vitamin D in February in Waterloo under ideal weather conditions, but not in most conditions. With this information, a guide has been created to optimize UVB for outdoor spaces in all seasons that children may use in northern climates. The design guide includes a summary of the geophysical variables that affect how much UVB reaches the earth’s surface and key concepts to understand including the difference between diffuse and direct radiation. This study provides evidence-based research in the area of climate responsive landscape architecture. / Landscape Architecture Canada Foundation

Climate responsive vernacular architecture: Jharkhand, India

Gautam, Avinash

January 1900

Master of Science / Department of Architecture / R. Todd Gabbard / This research aims to explore and assess passive solar design techniques that promote high thermal comfort in vernacular houses of the state of Jharkhand in India. The study of these houses provides useful insights for designing energy efficient houses that provide thermally comfortable conditions. An analysis of these houses in Ranchi, the capital city of Jharkhand, India provides a context for the field research. Jharkhand predominantly has two different styles of vernacular houses: huts and havelis. These houses were constructed, without any mechanical means, in such a manner as to create micro-climates inside them to provide high thermal comfort levels. Hence the study of thermal comfort levels in these buildings in relation to built environment in today's context is significant. As part of data collection, interviews were conducted with the occupants of ten houses in Ranchi, in June 2007. Two houses of each (huts and havelis) were selected for detailed experimental analysis. Experiment results indicated that all the four selected houses exhibited lower ambient temperature than outside during the day and a higher ambient temperature at night. Brick bat coba and lime mortar were the key materials used for constructing high thermal-mass walls. Adequate ventilation is significant in creating conditions that are comfortable. Aperture to volume ratio of less than 0.051 is not adequate enough to cool the thermal mass of these houses. These houses also use attic space to mitigate the heat gain from the roof. Courtyards and other exterior spaces form an integral part of these houses and influence the thermal conditions in and around the houses. The case studies show that there is a scope for more relaxation of comfort temperature range based on culture and phenomenon of acclimatization. A universal approach in understanding and defining comfort condition fails because the users of these houses were comfortable in conditions defined as uncomfortable by ASHRAE and Nicol.

Vernacular architecture

Climate responsive

Thermal comfort

India

Architecture (0729)

Energy (0791)

Engineering, Environmental (0775)

Parametric Performance-Driven Passive Solar Designed Facade Systems

Shorey, Thomas Paul, Jr.

01 March 2015

Buildings in the United States account for nearly 68% of all U.S. energy consumption due to their reliance on electrical lighting and mechanical systems. Beginning in the 20th century, emphasis on developing the glass curtain wall created increased energy demands on lighting and mechanical systems. Consequently, the building’s curtain wall is a direct cause of significant energy loads. This research project investigated how current parametric design tools and energy analysis software are used during a performance-driven passive solar design process to develop facade systems that lower the energy use intensity (EUI) of a building and increase natural daylight to an acceptable illuminance level (lux). Passive solar shading strategies were employed to realize the proposed design process through a proof of concept project that retrofits the facade of an outdated office building in a hot-mediterranean climate. Incremental steps were taken using parametric software (Revit Architecture 2015) to increase the passive solar and daylighting performance capabilities of the facade system and Autodesk Green Building Studio was employed to measure, compare and contrast the results of each design.

Climate Responsive Design

Parametric Design

Performance-based Design

Performance-driven Design

Passive Design

Sustainable Design

Architectural Technology

Environmental Design