Implementing vertical gardens in educational buildings to reduce energy consumption and achieve low carbon emissions
ElDamshiry, K., Abu Bakr, A., ElAttar, M. (2025). Implementing vertical gardens in educational buildings to reduce energy consumption and achieve low carbon emissions. EKB Journal Management System, 16(16), 1-1. doi: 10.1088/1755-1315/1530/1/012003
K K ElDamshiry; A Abu Bakr; M E ElAttar. "Implementing vertical gardens in educational buildings to reduce energy consumption and achieve low carbon emissions". EKB Journal Management System, 16, 16, 2025, 1-1. doi: 10.1088/1755-1315/1530/1/012003
ElDamshiry, K., Abu Bakr, A., ElAttar, M. (2025). 'Implementing vertical gardens in educational buildings to reduce energy consumption and achieve low carbon emissions', EKB Journal Management System, 16(16), pp. 1-1. doi: 10.1088/1755-1315/1530/1/012003
ElDamshiry, K., Abu Bakr, A., ElAttar, M. Implementing vertical gardens in educational buildings to reduce energy consumption and achieve low carbon emissions. EKB Journal Management System, 2025; 16(16): 1-1. doi: 10.1088/1755-1315/1530/1/012003

Implementing vertical gardens in educational buildings to reduce energy consumption and achieve low carbon emissions

The International Conference on Civil and Architecture Engineering
Volume 16, Issue 16, May 2025, Pages 1-1    PDF (289.62 K)
DOI: 10.1088/1755-1315/1530/1/012003
Authors
K K ElDamshiry1; A Abu Bakr2; M E ElAttar3
1Assistant Professor, Architecture Engineering Department, The British University in Egypt, El-Sherouk City, Egypt.
2Senior Student, Archite
3Professor, Architecture Engineering Department, The British University in Egypt, El- Sherouk City, Egypt.
Abstract
Abstract. Nowadays, the change of climate has been a crucial problem for
architects to address since buildings consume more than half of the energy that
results in carbon dioxide emissions that contribute to climate change. Vertical
gardens have been proven in studies to be capable of significantly offsetting
carbon dioxide emissions from building. in addition to passively cooling and
insulating the structure As a result, the energy required for building operation is
lowered in what appears to be a butterfly effect. The bulk of non-residential
buildings in Egypt have been built without regard for energy efficiency regulations
in recent years. As a result, mismatched designs are frequently responsible for
environmental problems. Energy usage is influenced by building design (form,
orientation, and building materials), as well as operational and space utilization
factors. Because non-residential buildings are among the most carbon-intensive
structures, greening current structures to achieve zero-carbon status is far more
efficient than greening new ones. This study investigates if adding vertical gardens
in Cairo buildings might serve as a passive cooling load reduction approach. This
is accomplished by calculating the building energy required for cooling load,
carbon dioxide emissions from cooling load, cooling load reduction made by
vertical gardens, and CO2 sequestered by vertical gardens, with the goal of
providing a guide that quantifies the vertical gardens system's efficiency to
minimize energy usage and carbon dioxide emissions. Through simulation, it was
found that living walls with mentha and spicata could reduce as much as 6200
watts and offset 5204kg of carbon dioxide emission.
Keywords
Climate Change; Urban Heat Island; Vertical Green System; Energy Efficiency; Low Carbon; Carbon Sequestration; Educational Buildings
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