Conradie, Dirk CU2012-08-242012-08-242012-07Conradie, DCU. South Africa’s climatic zones: today, tomorrow. International Green Building Conference and Exhibition: Future Trends and Issues Impacting on the Built Environment, 25-26 July 2012, Sandton, South Africahttp://hdl.handle.net/10204/6064International Green Building Conference and Exhibition: Future Trends and Issues Impacting on the Built Environment, 25-26 July 2012, Sandton, South AfricaTo design energy efficient buildings using an optimal combination of passive design strategies it is necessary to understand the particular climate designed for. To use energy simulation software such as EnergyPlusTM, EcotectTM or DesignBuilderTM to calculate building energy consumption or undertake a predictive thermal simulation of naturally ventilated buildings requires a detailed set of specially structured electronic weather data files such as the epw, tmy and iwec formats widely available in the U.S.A. Unfortunately there is a lack of these in South Africa. On the EnergyPlusTM website there are only two weather files available for South Africa in contrast to 1 479 for the U.S.A. If the MeteonormTM software is acquired a further 34 directly measured meteorological stations (weather files) are available for South Africa. Weather files for in between locations in the software mentioned are created by means of sophisticated interpolation formulas. Recently the South African SANS 204-2 standard introduced six main climatic zone region map in an attempt to inter alia establish the maximum energy demand and maximum energy consumption in the design of a particular building. This was a first step to introduce a more quantified view of climate regions into the South African National Building Standards. The question is raised whether this approach is adequate to optimally support medium to long term design decisions within the built environment for simulating and quantifying passive design strategies such as natural ventilation, thermal mass and passive solar heating. As a first stage to address this shortcoming it was decided to create a highly detailed climatic map of South Africa using 20 years of precipitation and temperature data using a Köppen-Geiger climatic classification to provide better general insight than the six-zone model. After this the predicted climate change over the next 100 years expressed as Köppen categories was researched.enClimatic classificationKöppen-Geiger mapBiocliomatic chartClimate changeBuilt environment sustainabilityGreen buildings2012 International Green Building Conference and ExhibitionSouth Africa’s climatic zones: today, tomorrowConference PresentationConradie, D. C. (2012). South Africa’s climatic zones: today, tomorrow. http://hdl.handle.net/10204/6064Conradie, Dirk CU. "South Africa’s climatic zones: today, tomorrow." (2012): http://hdl.handle.net/10204/6064Conradie DC, South Africa’s climatic zones: today, tomorrow; 2012. http://hdl.handle.net/10204/6064 .TY - Conference Presentation AU - Conradie, Dirk CU AB - To design energy efficient buildings using an optimal combination of passive design strategies it is necessary to understand the particular climate designed for. To use energy simulation software such as EnergyPlusTM, EcotectTM or DesignBuilderTM to calculate building energy consumption or undertake a predictive thermal simulation of naturally ventilated buildings requires a detailed set of specially structured electronic weather data files such as the epw, tmy and iwec formats widely available in the U.S.A. Unfortunately there is a lack of these in South Africa. On the EnergyPlusTM website there are only two weather files available for South Africa in contrast to 1 479 for the U.S.A. If the MeteonormTM software is acquired a further 34 directly measured meteorological stations (weather files) are available for South Africa. Weather files for in between locations in the software mentioned are created by means of sophisticated interpolation formulas. Recently the South African SANS 204-2 standard introduced six main climatic zone region map in an attempt to inter alia establish the maximum energy demand and maximum energy consumption in the design of a particular building. This was a first step to introduce a more quantified view of climate regions into the South African National Building Standards. The question is raised whether this approach is adequate to optimally support medium to long term design decisions within the built environment for simulating and quantifying passive design strategies such as natural ventilation, thermal mass and passive solar heating. As a first stage to address this shortcoming it was decided to create a highly detailed climatic map of South Africa using 20 years of precipitation and temperature data using a Köppen-Geiger climatic classification to provide better general insight than the six-zone model. After this the predicted climate change over the next 100 years expressed as Köppen categories was researched. DA - 2012-07 DB - ResearchSpace DP - CSIR KW - Climatic classification KW - Köppen-Geiger map KW - Biocliomatic chart KW - Climate change KW - Built environment sustainability KW - Green buildings KW - 2012 International Green Building Conference and Exhibition LK - https://researchspace.csir.co.za PY - 2012 T1 - South Africa’s climatic zones: today, tomorrow TI - South Africa’s climatic zones: today, tomorrow UR - http://hdl.handle.net/10204/6064 ER -