Access the full text.
Sign up today, get DeepDyve free for 14 days.
R. Grojean, J. Sousa, M. Henry (1980)
Utilization of solar radiation by polar animals: an optical model for pelts.Applied optics, 19 3
C. Stoppel, Fernanda Leite (2013)
Evaluating building energy model performance of LEED buildings: Identifying potential sources of error through aggregate analysisEnergy and Buildings, 65
N. Zhao, Zhen Wang, Chao Cai, Hengyu Shen, F. Liang, Dong Wang, Chunyan Wang, T. Zhu, Jing Guo, Yongxin Wang, Xiaofang Liu, Chunting Duan, H. Wang, Y. Mao, Xin Jia, Haixia Dong, Xiao-li Zhang, Jian Xu (2014)
Bioinspired Materials: from Low to High Dimensional StructureAdvanced Materials, 26
Reem Elsamadisy, A. Sarhan, Y. Farghaly, A. Mamdouh (2019)
BIOMIMICRYAS A DESIGN APPROACH FOR ADAPTATIONJournal of Al-Azhar University Engineering Sector
A. Gilavand, Mohammadreza Gilavand, Sakineh Gilavand (2016)
Investigating the Impact of Lighting Educational Spaces on Learning and Academic Achievement of Elementary StudentsInternational Journal of Pediatrics, 4
Michael Helms, Swaroop Vattam, Ashok Goel (2009)
Biologically inspired design: process and productsDesign Studies, 30
Emilie Snell‐Rood (2016)
Interdisciplinarity: Bring biologists into biomimeticsNature, 529
Mohamad Khattab, H. Tributsch (2015)
Fibre-Optical Light Scattering Technology in Polar Bear Hair: A Re-Evaluation and New Results, 3
C. Bohren, J. Sardie (1981)
Utilization of solar radiation by polar animals: an optical model for pelts; an alternative explanation.Applied optics, 20 11
(2006)
CN-Peking-Swimming Center 2008-442--26.09.06[.jpg]
S. Kalogirou (2004)
Solar thermal collectors and applicationsProgress in Energy and Combustion Science, 30
(2008)
CouncilHouse2[.jpg]
R. El-Zeiny (2012)
Biomimicry as a Problem Solving Methodology in Interior ArchitectureProcedia - Social and Behavioral Sciences, 50
(2015)
Biomimicry-an alternative solution to sustainable buildings
M. Kwon, H. Remøy (2019)
Office employee satisfaction: the influence of design factors on psychological user satisfactionFacilities
Ajla Aksamija, Abul Abdullah, Ben Cross (2014)
Whole Building Energy Analysis: A Comparative Study of Different Simulation Tools and Applications in Architectural Design
J. Kay (2003)
On complexity theory, exergy, and industrial ecology : Some implications for construction ecology
L. Heschong, R. Wright, S. Okura (2002)
Daylighting Impacts on Human Performance in SchoolJournal of The Illuminating Engineering Society, 31
(2005)
Micrograph of hook and loop fastener[.jpg]
(2005)
The integrated design process of CH2
(2021)
EnergyPlus
(2013)
Daylight and productivity in a school library”, in
N. Øritsland, K. Ronald (1978)
Solar heating of mammals: Observations of hair transmittanceInternational Journal of Biometeorology, 22
J. Lovelock (1972)
Gaia as seen through the atmosphereAtmospheric Environment, 6
Felix Tjenggoro, K. Prasetyo (2018)
The usage of green building concept to reduce operating costs (study case of PT. Prodia Widyahusada)Asian Journal of Accounting Research
(2021)
DesignBuilder software Ltd.
O. Schmitt (1969)
Biological Information Processing Using the Concept of Interpenetrating Domains
H. Tributsch, H. Goslowsky, U. Küppers, H. Wetzel (1990)
Light collection and solar sensing through the polar bear peltSolar Energy Materials, 21
(2006)
CH2[.jpg]
(2021)
Arctium lappa TK[.jpg]
M. Arkinstall, T. Carfrae, Xueyi Fu (2011)
Integrated Multidisciplinary Design and Construction of the Beijing National Aquatic Centre, ChinaStructural Engineering International, 21
Niina Leskinen, J. Vimpari, S. Junnila (2020)
The impact of renewable on-site energy production on property valuesJournal of European Real Estate Research, 13
Qingli Wang, Ji-Huan He, Zheng-Biao Li (2012)
Fractional model for heat conduction in polar bear hairsThermal Science, 16
(2018)
Energy star score for K-12 schools
G. Radwan, Nouran Osama (2016)
Biomimicry, an Approach, for Energy Effecient Building Skin DesignProcedia environmental sciences, 34
K. Schmidt‐Nielsen (1964)
Desert Animals: Physiological Problems of Heat and Water
Fangxian Wang, Jian Liu, X. Fang, Zhengguo Zhang (2016)
Graphite nanoparticles-dispersed paraffin/water emulsion with enhanced thermal-physical property and photo-thermal performanceSolar Energy Materials and Solar Cells, 147
(2016)
Kingfisher Bird[.jpg]
Tonia Gray, Carole Birrell (2014)
Are Biophilic-Designed Site Office Buildings Linked to Health Benefits and High Performing Occupants?International Journal of Environmental Research and Public Health, 11
M. Zari, J. Storey (2007)
An ecosystem based biomimetic theory for a regenerative built environment
Construction Ecology: Nature As the Basis for Green Buildings
Catherine Ryan, W. Browning, Joseph Clancy, Scott Andrews, Namita Kallianpurkar (2014)
BIOPHILIC DESIGN PATTERNS: Emerging Nature-Based Parameters for Health and Well-Being in the Built EnvironmentInternational Journal of Architectural Research: Archnet-IJAR, 8
A. Gamage, R. Hyde (2012)
A model based on Biomimicry to enhance ecologically sustainable designArchitectural Science Review, 55
Ji-Huan He, Qingli Wang, Jie Sun (2011)
Can polar bear hairs absorb environmental energyThermal Science, 15
Elisabeth Endres, Michael Fischer, Friedemann Jung (2010)
Energy and buildings
M.H. Nicklas, G.B. Bailey (1996)
Analysis of the performance of students in daylit schools
R. Diamond (2006)
Evaluating the energy performance of the first generation of LEED-certified commercial buildingsLawrence Berkeley National Laboratory
(1987)
Warming up to polar bears’ solar secrets. Studies of their hollow fur may lead to more efficient solar energy technologies
Hao Jia, Jingjing Zhu, Zhaoling Li, Xiaomei Cheng, Jiansheng Guo (2017)
Design and optimization of a photo-thermal energy conversion model based on polar bear hairSolar Energy Materials and Solar Cells, 159
Energy and Buildings, 41
(2019)
MXX facts
The purpose of this study is to examine the energy savings in the indoor environment, using strategies that adopt the characteristics of nature, called biomimetic solutions. This research designed a biomimetic window system to bring daylight into interior spaces in educational buildings where daylight cannot be reached. Specifically, this study assessed how the daylight that was achieved via a biomimetic window system would affect energy savings using an energy simulation method.Design/methodology/approachThis study explored how biomimetic methods would affect the building environment and which biomimetic method would involve the building's energy saving with daylight. The research intended to develop a novel biomimetic window system that can bring daylight to the basement floor of an existing building on a university campus to find out how much the biomimetic window system would affect the energy savings of the building. Referring to the existing building's layout and structure, energy simulation models were developed, and the energy consumptions were estimated.FindingsSimulation models proved that the biomimetic window system has sufficient performance to bring more daylight to the basement floor of the building. Furthermore, it was confirmed that the use of the biomimetic window system for the building could reduce energy usage compared to the actual energy usage of the current building without biomimetic windows.Research limitations/implicationsFirst, this study was adopted as a computer-designed simulation method instead of using a real-world system. Although this study designed the biomimetic window system based on previous studies, it should be considered the possibility of other problems when the system is actually built in. Second, it is necessary to predict how much an initial budget is required when the system is built. It means that this study did not calculate the lifecycle cost of the biomimetic window system. It will also be necessary to compare energy consumption to the required initial budget. Lastly, this study was simulated based on weather data in cold regions, and it did not compare/analyze different climate regions. Different results may be predicted if the biomimetic window system is built in different climatic regions.Originality/valueThis research showed new practical ways to capture and transmit solar heat and light using a biomimetic solution. Furthermore, using the proposed novel biomimetic window system, the amount of energy reduction can be calculated, and this method could be applied in the interior non-window spaces of academic and related types of buildings.
Open House International – Emerald Publishing
Published: Feb 3, 2023
Keywords: Biomimicry; Daylight; Building energy; Energy savings; Biomimetic window system
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.