Daylight Control in Greenhouse Environments Using Kinetic Skin and Annual Energy Consumption Optimization

Abdali, Pouria; Goldust, Yaser; Ahmadi, Ferial

doi:10.22034/bagh.2025.511783.5783

Daylight Control in Greenhouse Environments Using Kinetic Skin and Annual Energy Consumption Optimization

https://doi.org/10.22034/bagh.2025.511783.5783

Volume 22, Issue 146
August 2025

Pages 55-72

The Monthly Scientific Journal of Bagh-e Nazar

Document Type : Original Research Article

Authors

Pouria Abdali ¹

Yaser Goldust ¹

Ferial Ahmadi ²

¹ Faculty of Art and Architecture, University of Mazandaran, Babolsar, Iran.

² School of Public Health, University of Memphis, USA.

Abstract

Problem statement: Shade-loving plants are sensitive to high-light intensity and grow in low-light environments. These plants, which constitute a significant component of indoor green landscapes, require an illuminance range of 300 to 1000 lux for optimal growth. Conversely, greenhouses rely on energy-intensive mechanical and electronic equipment to maintain ideal growth conditions, leading to increased energy consumption. Consequently, controlling daylight and reducing energy use in these production units are of great importance. Kinetic skins, as a sustainable architectural solution, have been employed in this study and play a crucial role in daylight control and energy consumption reduction.
Research objective: This study aims to propose an adaptive envelope for controlling daylight in greenhouses designed for shade-loving plants while reducing energy consumption in Babolsar.
Research method: This research employed a quasi-experimental approach. Initially, theoretical studies were examined through a literature review, then a software-based model was developed in Rhino and Grasshopper. The proposed envelope design was inspired by the traditional Orosi windows of Mazandaran and consisted of three geometric patterns: square, circle, and Dodecagon. Energy and daylight simulations were performed using Honeybee and Ladybug, where the energy analysis was conducted with the OpenStudio engine and daylight analysis with Radiance.
Conclusion: Among the three geometric patterns, the square pattern demonstrated the best performance in terms of daylighting and energy efficiency. Based on the Useful Daylight Illuminance (UDI) index, this envelope provided optimal daylight conditions for 63.2% to 91.4% of the time while transmitting excessive illuminance above 1000 lux less frequently than the other patterns. Regarding the annual Energy Use Intensity (EUI) index, the square pattern recorded the lowest energy consumption at 154. 19 kWh/m², reducing energy consumption by 13.75% compared to the base model. The findings indicate that the square geometry outperforms circular and Dodecagon geometries in the design of adaptive greenhouse panels.

Keywords

Daylight Control

Kinetic Skin

Greenhouse Environment

Shade-Loving Plants

Energy Consumption Reduction

UDI and EUI Indicators

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