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http://dx.doi.org/10.13087/kosert.2018.21.3.99

Analysis of Growth Indicators of Applied Plants by AHU(Air Handling Unit)-linking with Artificial Soil-based Vegetation Bio-filters  

Kim, Tae-Han (Dept. of Environmental Landscape Architecture, Sang Myung University)
Lee, So-Dam (Dept. of Environmental Resources, Graduate School, Sang Myung University)
An, Byung-Ryul (Dept. of Civil Engineering, Sang Myung University)
Publication Information
Journal of the Korean Society of Environmental Restoration Technology / v.21, no.3, 2018 , pp. 99-110 More about this Journal
Abstract
Compared to yellow dust coming from China or particulate matter created naturally in spring due to Total Suspended Particulate(TSP), particulate matter in winter season have much more serious effect on human body as they penetrate cell membranes. Although such particulate matter are becoming a social issue, there are no concrete plans on how to reduce them. Air-purifying plants are limited in maintaining the indoor air quality of large area because it is usually difficult to quantify their performance. In order to improve this, a bio-filter that can be connected to air conditioner is suggested as an option. This study seeks to improve air conditioning model-based monitoring method for bio-filters from prior studies and objectify correlations between applied vegetation and growing environment into quantitative indicators. By doing so, this study seeks to provide criteria on plants applied to artificial soil-based vegetation bio-filters and basic information to set air-conditioning features. The study results confirmed significant tendency on the growing stability of each purifying plant in mechanical air-conditioning environment. Among three models selected for bio-filter vegetation models, epipremnum aureum showed high performance in quantitative indicators, including soil moisture, EC, and leaf temperature, etc., indicating that it would assure the highest growing stability in this test air-conditioning environment.
Keywords
Bio-filtration; Plant Growth Indicator; Soil Moisture; Soil Electrical Conductivity; Leaf Temperature;
Citations & Related Records
Times Cited By KSCI : 10  (Citation Analysis)
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