A Parametric Design Method for the Lighting Environment of a Library Building Based on Building Performance Evaluation
Abstract
:1. Introduction
2. Literature Review
3. Research Method
3.1. Determining Environmental Response Strategies and Environmental Lighting Performance Evaluation Indicators
3.2. Determining the Basic Parameters of the Building Model
3.3. Performing Photothermal Simulations of Building Skins
3.4. Disturbing Skin Changes to Generate Dynamic Skins
3.5. Simulation of Building Light Environmental Performance
4. Results and Discussion
4.1. Percentage of the Area with Different Hours of Illumination Greater than 300l×
4.2. Percentage of the Area with Different Hours of Useful Daylight Luminance
4.3. Daylight Glare Probability (DGP)
4.4. Discussions
5. Conclusions
- The skin changes of the design method must correspond to the sunshine duration and sunshine radiation, so that a building’s skin changes can be based on data. This will provide a more accurate parameterized design method based on data analysis.
- The research results show that a dynamic building skin based on sunshine duration and solar radiation can significantly improve the indoor light environment of a building on the summer solstice. The indoor illumination can be more comfortable and the probability of an uncomfortable glare can be reduced. In such a building, the indoor illumination will be less comfortable on the winter solstice, although the probability of an uncomfortable glare will be reduced.
- The research results reveal differences in the effect of the dynamic shading skin generated based on sunshine duration and sunshine radiation data of the indoor light environment comfort in rooms with different orientations. However, the differences are relatively similar, demonstrating an insignificant role.
- This research optimizes and evaluates a building’s environmental lighting performance with daily meteorological data to achieve more accurate skin optimization results.
- Taking sunshine duration and sunshine radiation as the influencing factors, this study conducts interference design on the dynamic skin of buildings, making the optimal design of building skin more scientific and effective.
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Author/Year | Building Type | Façade | Variable Parameter | Platform | Optimization Objective | Method |
---|---|---|---|---|---|---|
Mahmoud AHA, et al./2016 [25] | Office building | Dynamic façade (kinetic façades) | Rotation motion, translation motion | Grasshopper + DIVA | Daylight | Parametric modeling, simulation |
Hosseini S M, et al./2020 [26] | Traditional building | Dynamic façade | Window glass color, interior space partitions | Grasshopper + DIVA | Daylight | Parametric modeling, simulation |
Lin C H, et al./2022 [27] | Office building | Fixed façade | Aperture, aperture change rate, number of attraction points, random seed of attraction point positions, and panel thickness | Grasshopper + DIVA Expert systems | Daylight | Parametric modeling, machine learning, artificial neural network |
Yi Y K, et al./2019 [29] | Apartment | Fixed façade | Surface shape and amplitude, number of holes and size | Grasshopper | Daylight, aesthetic sensibilities | Parametric modeling, multiobjective optimization |
Nadiri P, et al./2019 [36] | Office building | Fixed façade | The number, depth, angle, and thickness of south façade louvers | Grasshopper (Ladybug + Honeybee + Galapagos) | Annual sun exposure, view to outside | Parametric modeling, simulation, optimization |
Chi D A, et al./2021 [37] | Office building | Fixed façade (perforated solar screens) | Orientations, perforation percentage, matrix, shape | Grasshopper + DIVA + Energy Plus | Daylight, thermal analysis | Parametric modeling, simulation |
Anzaniyan E, Chi D A, et al./2022 [38] | Office building | Dynamic façade (biokinetic façade) | Panel angle | Grasshopper (Ladybug + Honeybee) | Daylight, energy | Parametric modeling, simulation |
Bande L, et al./2022 [39] | Campus library | Dynamic façade | Folding mode | REVIT + Grasshopper (Ladybug, Honeybee, and Daysim) | Daylight energy | Parametric modeling, simulation |
Chi D A, et al./2017 [40] | Office building | Fixed façade (perforated solar screens) | Perforation percentage, matrix, shape | DIVA/Grasshopper/Archsim + EnergyPlus | Daylight energy | Parametric modeling, orthogonal, array simulation |
Season | Environmental Response Strategies |
---|---|
Summer | Avoid excessive heat and light in the room, focus on shade and protection from the sun, and prevent glare |
Winter | Combines shading and heat storage to prevent glare |
Spring & Autumn | Focus on shade and sun protection to prevent glare |
Indicator | Unit | Comfort Range |
---|---|---|
Daylight autonomy (DA) | % | DA_300l× ≥ 50% |
Useful daylight illuminance (UDI) | % | UDI (450~3000l×): an acceptable level of daylight |
Daylight glare probability (DGP) | % | DGP ≤ 0.35: undetectable glare |
Reflectance | Specularity | Roughness | Transmittance | Diffuse Reflectance | Diffuse Transmittance | |
---|---|---|---|---|---|---|
Ceiling | 0.75 | 0 | 0.05 | - | - | - |
Floor | 0.58 | 0 | 0.05 | - | - | - |
Wall | 0.75 | 0 | 0.05 | - | - | - |
Glass (Low-E 6 + 12A + 6c) | - | - | - | 0.68 | - | - |
Shade (PTFE) | - | - | 0.05 | - | 0.01 | 0.4 |
The Percentage of the Area of the Room with Different Hours of Luminance Greater than 300l× | The Percentage of the Area with Different Hours of Useful Daylight Luminance | DGP | ||||
---|---|---|---|---|---|---|
Summer Solstice | Winter Solstice | Summer Solstice | Winter Solstice | Summer Solstice | Winter Solstice | |
South | Sunlight radiation | Sunlight radiation | Sunlight hours | Sunlight radiation | Sunlight hours | Sunlight hours |
East | Sunlight radiation | Sunlight hours | Sunlight hours | Sunlight hours | Sunlight hours | Sunlight hours |
North | Sunlight radiation | Sunlight Radiation | Sunlight hours | Sunlight radiation | Sunlight hours | Sunlight Radiation |
West | Sunlight hours | Sunlight hours | Sunlight hours | Sunlight hours | Sunlight radiation | Sunlight hours |
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Liu, Q.; Han, X.; Yan, Y.; Ren, J. A Parametric Design Method for the Lighting Environment of a Library Building Based on Building Performance Evaluation. Energies 2023, 16, 832. https://doi.org/10.3390/en16020832
Liu Q, Han X, Yan Y, Ren J. A Parametric Design Method for the Lighting Environment of a Library Building Based on Building Performance Evaluation. Energies. 2023; 16(2):832. https://doi.org/10.3390/en16020832
Chicago/Turabian StyleLiu, Qibo, Xiao Han, Yuheng Yan, and Juan Ren. 2023. "A Parametric Design Method for the Lighting Environment of a Library Building Based on Building Performance Evaluation" Energies 16, no. 2: 832. https://doi.org/10.3390/en16020832
APA StyleLiu, Q., Han, X., Yan, Y., & Ren, J. (2023). A Parametric Design Method for the Lighting Environment of a Library Building Based on Building Performance Evaluation. Energies, 16(2), 832. https://doi.org/10.3390/en16020832