Fig. 1. Shape and surface of panel
Fig. 2. Examples of moss panels
Fig. 3. Moss growth accelerating equipment
Fig. 4. Evaluation of carbon dioxide reduction performance
Fig. 5. Evaluation of fine dust cleaning performance
Fig. 6. Flow results according to SAP
Fig. 7. Compressive strength results according to SAP
Fig. 8. pH range of OPC and AC
Fig. 9. Measurement results of moisture content of panel
Fig. 10. Measurement results of surface roughness of panel
Fig. 11. Porosity of panel surface
Fig. 12. Surface porosity of panel
Fig. 13. CO2 reduction performance of moss panel Fig. 14
Fig. 14. Fine dust cleaning performance of moss panel
Table 1. Chemical composition and physical properties of cement used in the experiment
Table 2. Physical properties of fine aggregate used in the experiment
Table 3. Physical properties of SAP used in the experiment
Table 4. Experimental plan and parameters for panel manufacturing
Table 5. Mix design
References
-
Park, E.H., Oh, C.H. (2011). "A study of
$CO_2$ reduction effect by preventing heat island," Proceeding of Korean Society of Environment and Ecology, 21(1), 133-141 [in Korean]. - Kim, S.B., Kim, G.H., Cho, J.H. (2001). The urban heat island phenomenon and potential mitigation strategies, Journal of Nakdong River Environmental Research Institute, 6(1), 63-89 [in Korean].
- Myung, S.J. (2015). "The effect of green area in urban area on mitigation of urban heat island," Proceeding of Korean Meteorological Society, 2, 402-403 [in Korean].
- Chae, C.U., Suh, C.H. (1994). "An experimental study on the lightweight precast concrete panel development," Proceeding of the Architectural Institute of Korea, 14(1), 521-524 [in Korean].
- Kim, T.H., Li, F.Q., Ahn, T.W., Choi, I.S., Oh, J.M. (2011). Research on improvement of water purification efficiency by concrete using bio film, Journal of Environmental Impact Assessment, 20(6), 815-821 [in Korean]. https://doi.org/10.14249/EIA.2011.20.6.815
- Perini, K., Ottele, M., Haas, E., Raiteri, R. (2011). Greening the building envelope, facade greening and living wall systems, Journal of Ecology, 1(1), 1-8.
- Choi, Y.W., Lee, J.H., Choi, B.K., Oh, S.R. (2017). Workability and compressive strength properties of magnesia-potassium phosphate composites for biological panel, Journal of the Korea Academia-Industrial Cooperation Society, 18(7), 357-364. https://doi.org/10.5762/KAIS.2017.18.7.357
- Choi, Y.W., Oh, S.R., Lee, J.H., Jeong, J.G. (2018a). An experimental study on the quality properties of foamed cement composite materials for biological panels applying post-foaming method, Journal of Korea Concrete Institute, 30(1), 15-22 [in Korean]. https://doi.org/10.4334/JKCI.2018.30.1.015
- Choi, Y.W., Oh, S.R., Kim, C.G., Lee, J.H. (2018b). A study on the fundamental quality of magnesia-phosphate-formed mortar composites using superabsorbent polymer for development of concrete for biological panel, Journal of Advances in Materials Science and Engineering, 2018, 1-8.
- Lee, J.H. (2018). A Study on the Quality Properties of Biological Lightweight Panels by Magnesiaa Composites, Master's Thesis, Semyung University, Korea [in Korean].
- Choi, Y.W., Oh, S.R., Kim, C.G., Nam, E.J., Joo, H.J., Hwang, E.S. (2018c). "An experimental study on the growth characteristics of moss for biological concrete panels," Proceeding of the Korean Recycled construction Resources Institute, 2, 124-126 [in Korean].
- Choi, Y.W., Oh, S.R., Kim, C.G., Lee, J.H., Nam, E.J., Jeong, J.G. (2018d). "An experimental study on the bioreceptivity of magnesia-potassium phosphate composites using accelerated bryophyte test," Proceeding of the Korean Recycled construction Resources Institute, 1, 105-106 [in Korean].