Full-Scale Experimental Investigation of the Influence of Solar Radiation on the Thermal Behavior of Ventilated Façade Envelope Systems Under Hot Climate Conditions

Zhangabay N. Zhangabay A. Utelbayeva A. Tursunkululy T. Zakaria R. Bakhbergen S.
January 2026 Multidisciplinary Digital Publishing Institute (MDPI)

Buildings
2026 #16 Issue 1

The article presents the results of a comprehensive full-scale investigation of the influence of solar radiation on the thermal behavior of the exterior envelope systems of two residential buildings of different heights—a 9-storey building in Turkestan and a 25-storey building in Shymkent. The façade systems of both buildings consist of a multilayer enclosure with a ventilated air cavity, 100 mm wide in the 9-storey building and 50 mm wide in the 25-storey building. The objective of the study was to determine the diurnal and vertical dynamics of temperature fields, analyze the thermal inertia of the materials, and assess the effect of façade geometry on heat-transfer performance. Thermographic measurements were carried out during key periods of the day (7:00, 10:00, 13:00, and 17:00), which enabled coverage of the full solar-insolation cycle. The results showed that the maximum temperatures of the external cladding reached 48–52 °C for the 9-storey building and 53–58 °C for the 25-storey building, with a vertical temperature gradient of 3–7 °C. The temperature of the interior surface varied within 28–32 °C and 29–34 °C, respectively, reflecting the influence of both solar heating and the width of the ventilation cavity on heat transfer. It was found that reducing the air-gap width intensifies natural convection and decreases the thermal inertia of the system, resulting in sharper temperature fluctuations. The study demonstrates that current design standards insufficiently account for the vertical non-uniformity of solar exposure and the aerodynamic processes within the ventilation channel. The findings can be used in the design of energy-efficient façade systems, in the refinement of regulatory methodologies, and in the development of heat-transfer models for high-rise buildings under conditions of increased solar radiation.

high-rise buildings , natural convection , solar radiation , temperature field , thermal inertia , ventilated façade

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Scientific Research Laboratory of Mechanical Engineering Problems, M. Auezov South Kazakhstan University, Tauke Khan Av., 5, Shymkent, 160012, Kazakhstan
Department of Construction and Building Materials, Satbayev University, Satbayev Av., 22, Almaty, 050013, Kazakhstan
Department of Chemistry, M. Auezov South Kazakhstan University, Tauke Khan Av., 5, Shymkent, 160012, Kazakhstan
Department of Architecture and Urban Planning, M. Auezov South Kazakhstan University, Tauke Khan Av., 5, Shymkent, 160012, Kazakhstan
Faculty of Artifical Intelligance, Department of Smart Engineering and advanced Technology, Universiti Teknologi Malaysia, Kuala Lumpur, 54100, Malaysia

Scientific Research Laboratory of Mechanical Engineering Problems
Department of Construction and Building Materials
Department of Chemistry
Department of Architecture and Urban Planning
Faculty of Artifical Intelligance

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