A Suggestion of the Alternatives Evaluation Method through IFC-Based Building Energy Performance Analysis
Abstract
:1. Introduction
1.1. Research Background
1.2. Literature Review
1.2.1. Evaluation Method for Building Design Alternatives
1.2.2. Analysis of Building Energy Performance
1.2.3. Deriving Analysis Results and Implications
2. Methodology for Creating IFC-Based Building Envelope Automation Alternatives
2.1. Deriving Design Elements for Energy Performance Evaluation
2.2. Suggestion of IFC Data Exchange Structure
2.3. Development of Automated Building Envelope Form Generation System
3. Evaluation of Alternative Automation for Building Envelope Based on IFC
3.1. Development of Building Envelope Alternative Evaluation System
3.2. Analysis and Verification Results for Buildinig Envelope Alternative Evaluation System
- (1)
- Conducting load (IfcSlab (top), IfcSlab (base), IfcCurtainWall) = Area (IfcElementQuantity) × U-value (Pest_CurtainWallCommon-ThermalTransmittance) × design temperature.
- (2)
- Solar load (IfcCurtainWall) = Area (IfCElementQuantity) × SHGC (Pest_DoorWindowGlazingType-SolarHeatGainTransmittance) × SolarAbsorption.
- (3)
- Human body heat + Equipment heat + Light heat (see basic analysis conditions in Table 3).
- (1)
- Conducting load (IfcSlab (top), IfcSlab (base), IfcCurtainWall) = Area (IfcElementQuantity) × U-value (Pest_CurtainWallCommon-ThermalTransmittance) × design temperature.
- (4)
- Infiltration heat (see basic analysis conditions in Table 3).
4. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Type of Information | Information Needed | Required | Optional | Data Type | Units |
---|---|---|---|---|---|
Building Elements (Opaque-Wall, Roof, Floor, Ceiling, Door) | Added to the list above, the following properties should be included for opaque building elements (e.g., walls, floors, ceilings, roofs, doors, etc.) | ||||
Composite Thermal Resistance | X | Real | m2-K/W | ||
Building Elements (Glazing-Curtain Wall, Glazed Door, Skylight, Window) | Windows, curtain walls, glazed doors, and skylights | ||||
Window Assembly Exterior Surface Color of Glass (clear, bronze, silver, gold, copper, blue, green, gray, mirror) | X | Enum | n/a | ||
Window Assembly Interior Surface Color of Glass (clear, bronze, silver, gold, copper, blue, green, gray, mirror) | X | Enum | n/a | ||
Transmittance (Visible) | X | Real | % | ||
Transmittance (Solar) | X | Real | % | ||
Composite U-Value | X | Real | W/m2-K | ||
Shading Coefficient (SC) | X | Real | % | ||
Solar Heat Gain Coefficient (SHGC) | X | Real | % | ||
Manufacturer | X | String | n/a | ||
Product ID | X | String | n/a |
Division | ALT 1 | ALT 2 | ALT 3 |
---|---|---|---|
IFC Building Envelope Data | Polygonal Type: 6 Radius: 30 m | Rectangular Dimension: 30 m × 30 m | Circular Radius 1: 30 m Radius 2: 30 m |
S/W | Grasshopper (Geometry Gym Plugin) | ||
IFC ver. | IFC2 × 3 |
Division | Contents | |
---|---|---|
Location | Seoul | |
Latitude | 37.313394 | |
Longitude | 126.554151 | |
Scale | Height | 318 m |
Storey | 69 | |
Sky height | 4.6 | |
Design Temperature | Cooling(°C) | Outside: 32 °C Inside: 27 °C |
Heating (°C) | Outside: −8 °C Inside: 20 °C | |
Indoor Heat | Occupant (W/m2) | Sensible heat: 20 Latent heat: 35 Residence density: 31 |
Light (W/m2) | 20 | |
Equipment (W/m2) | 20 | |
Infiltration | Air change | 0.5 ac/h |
U-value | External wall | 0.47 |
Roof | 0.29 | |
Slab | 0.58 | |
Window/Door | 3.40 | |
SHGC | Window/Door | 0.53 |
Solar Absorption | Window/Door | 0.50 |
ALT 1 | ALT 2 | ALT 3 | ||||
---|---|---|---|---|---|---|
Cooling (kW) | Heating (kW) | Cooling (kW) | Heating (kW) | Cooling (kW) | Heating (kW) | |
External wall conduction | 80.9 | 96 | 67.9 | 96 | 93.9 | 96 |
Roof conduction | 62.9 | 95.2 | 58.5 | 88.5 | 69 | 98.5 |
Window conduction | 187.1 | 351.6 | 160.8 | 250.9 | 460.8 | 390.9 |
Window sunrise | 590.8 | - | 331.6 | - | 691.6 | - |
Occupational heat | 185 | - | 185 | - | 185 | - |
Light heat | 298 | - | 298 | - | 298 | - |
Equipment heat | 385.1 | - | 385.1 | - | 385.1 | - |
Intrusion outside | 190.2 | 194.9 | 190.2 | 194.9 | 190.2 | 194.9 |
Total | 1980.0 | 737.7 | 1677.1 | 630.3 | 2373.6 | 780.3 |
ALT 1 | ALT 2 | ALT 3 | ||||
---|---|---|---|---|---|---|
Cooling (kW) | Heating (kW) | Cooling (kW) | Heating (kW) | Cooling (kW) | Heating (kW) | |
Evaluation program developed in this study | 1980.0 | 737.7 | 1677.1 | 630.3 | 2373.6 | 780.3 |
EnergyPlus | 2017.9 | 749.5 | 1720.9 | 640.8 | 2429.6 | 791.2 |
Difference | −37.9 (1.97%) | −11.8 (1.65%) | −43.8 (2.70%) | −10.5 (1.73%) | −56 (2.42%) | −10.9 (1.44%) |
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Choi, J.; Lee, S. A Suggestion of the Alternatives Evaluation Method through IFC-Based Building Energy Performance Analysis. Sustainability 2023, 15, 1797. https://doi.org/10.3390/su15031797
Choi J, Lee S. A Suggestion of the Alternatives Evaluation Method through IFC-Based Building Energy Performance Analysis. Sustainability. 2023; 15(3):1797. https://doi.org/10.3390/su15031797
Chicago/Turabian StyleChoi, Jungsik, and Sejin Lee. 2023. "A Suggestion of the Alternatives Evaluation Method through IFC-Based Building Energy Performance Analysis" Sustainability 15, no. 3: 1797. https://doi.org/10.3390/su15031797
APA StyleChoi, J., & Lee, S. (2023). A Suggestion of the Alternatives Evaluation Method through IFC-Based Building Energy Performance Analysis. Sustainability, 15(3), 1797. https://doi.org/10.3390/su15031797