dc.description.abstract |
Converting existing sloped roofs to green roofs in Sri Lanka poses challenges due to limited
options and costly modifications. This research aims to overcome these barriers by developing
a modular roof tile system that enables a smooth and cost-effective transition to green roofs.
The proposed system allows for easy replacement of current roofing materials with green roof
tiles, minimising the need for major modifications to the existing roof support system. By
considering the tropical climate conditions of Sri Lanka, this research fills the gap in green roof
studies primarily conducted in temperate regions. The study focuses on determining optimal
dimensions and profiles for modular roof tiles through structural analysis and computer
simulations.
The methodology employed in the research study was as follows. Initially, a literature review
was conducted to gather information on green roofs, research gaps, and roof structure details
specific to Sri Lanka. Then examined existing roofing systems in Sri Lanka to understand their
characteristics and installation methods. Suitable dimensions for the proposed green roof tile
were decided based on the literature review, the study of roofing systems in Sri Lanka, and a
laboriousness study. Suitable dimensions were identified as 900mm x 1200mm x 25 mm. Then
suitable profiles were selected for the green roof tile based on existing roof tiles and relevant
literature. Finite element modelling was utilised to analyse the structural behaviour of the
proposed roof tile profiles and identify the most suitable profile for optimal performance. Three
initial shapes of corrugations were considered first to determine the best shape. Based on the
comparative study of the three different corrugation shapes, it was determined that circular
corrugation exhibited the highest reduction in maximum displacement per unit length increased
through the introduction of corrugation. To explore the design variations within this profile,
the rise and pitch of the circular corrugation were systematically varied, resulting in a total of
nine different profiles. During the comparative study of the nine profiles, a specific criterion
was applied to select the most suitable profile. Only the profiles that exhibited a displacement
of less than or equal to 5mm were considered for further evaluation. Among these profiles, the
focus was on identifying the one that demonstrated the highest reduction in maximum
displacement per unit length increased through the introduction of corrugation compared to the
base profile. After careful analysis and assessment, profile with a rise of 10mm and a pitch of
200mm emerged as the optimal choice, exhibiting a significant reduction in displacement, and
fulfilling the established criteria. Thus, this profile was selected as the preferred profile for the
proposed green roof tile system. The recommended profile demonstrates significant
displacement reduction per unit length increased through the introduction of corrugation and
offers favourable characteristics for accommodating the growing medium.
The findings will contribute to promoting sustainable construction practices by providing costeffective
solutions for converting existing sloped roofs to green roofs in Sri Lanka. |
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