The Use of Normative Energy Calculation beyond the Optimum Retrofit Solutions in Primary Design: A Case Study of Existing Buildings on a Campus
Abstract
:1. Introduction
1.1. Performance-Driven Architectural Design
1.2. Application Feasibility of the Normative Energy Calculation in Building Performance Prediction
2. Methodology
2.1. Building Prototype
2.2. Shading Analysis
2.3. Data Optimization
- The non-weighted method: It calculated the average of all four sets of comparisons throughout the whole year.
- The weighted method: It calculated the average value of the differences multiplied by the established weights. This formulation is convenient because it enables the user to consider impact weights for the building data. This is performed on a monthly basis for each set of building data. Whenever weight is specified as zero, it means that the respective set or the respective month is not considered in the calibration process. The range of variation of the weights is defined in the maximum and minimum weight cells.
If there is district heating (user decision), then Hdi = 1 ELSE Hdi = 0.
If there is a district cooling source, then Cdi = 1 ELSE Cdi = 0.
2.4. Scenarios and Criteria
3. Results
3.1. Shading Analysis
3.2. Data Optimization
3.3. Renovation Strategy Ranking and Primary Design Scheme
4. Discussion
4.1. Limitations and Effects on the EPC Calculation
4.2. Discussion on Performance-Driven Architectural Design and Its Theory and Ethics
5. Conclusions
Author Contributions
Funding
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Building Total Ventilated Volume [m3] | Building Height [m] | Envelope Heat Capacity [J/K] | Cooling System Full Load COP | Material | |||
---|---|---|---|---|---|---|---|
Roof U-Value [W/m2/K] | Opaque U-Value [W/m2/K] | Window U-Value [W/m2/K] | SHGC | ||||
9083.00 | 13.80 | Medium: 165,000*Af | 4.10 | 0.45 | 0.70 | 2.67 | 0.20 |
Climate Zone | Representative City | Main Building Design Information | |||||||
---|---|---|---|---|---|---|---|---|---|
General Geometry | Envelope Heat Capacity (J/K) | Building Energy Management System | Temperature Setpoint [°C] | ||||||
3A, ASHRAE Standard | Atlanta | Volume [m3] | Wall [m2] | Window [m2] | Window Overhang Direction and Angle [degrees] | Heavy (260,000*Af) | No building automation function | For heating | For cooling |
14,000 | 1650 | 390 | SW (30) | 21 | 24 |
Inputs | Variable Limits | Reference | ||
---|---|---|---|---|
Parameter | Unit | Minimum | Maximum | |
Heating COP | kW/kW | 0.5 | 5 | Based on the typical VAV cooling system general values |
Cooling COP | kW/kW | 0.5 | 5 | |
Building air leakage level | (m3/h)/m2 | 0.05 | 2.2 | Building air leakage level and ASHRAE 90.1-2019: B2 Compliance [32] |
Appliance-OF | W/m2 | 6 | 11 | For the light-weight partition interior, considering 200–250 W/m2 equal to 1 computer/m2, thus, we gave a range 1–100 for office rooms; 30–750 for serves rooms |
Lighting-OF | W/m2 | 5 | 12 | A standard official open-plan consists of three-lamp luminaires spaced is set at 8 ft. × 10 ft. (2.4 m × 3 m) (Lighting and Standard 90.1-ASHRAE) Older technologies of T12 lamps and magnetic ballasts will result in an LPD range of 1.2 to1.4 W/ft2 (12.9 to15 W/m2), which exceeds the maximum of 1 W/ft2 (10.8 W/m2) allowed under the ASHRAE 90.1-2016 [33] |
Appliance-MC | W/m2 | 350 | 750 | ASHRAE Handbook—HVAC Applications |
Lighting-MC | W/m2 | 5 | 20 | ASHRAE Handbook—HVAC Applications |
Outdoor Air | liter/s/person | 5 | 15 | ASHRAE Fundamental (SI) |
DHW | liter/m2/month | 0.05 | 10 | ASHRAE Fundamental (SI) |
Optimization | Technology Levels | Cost ($) | Reference |
---|---|---|---|
Lighting daylighting factor | Baseline (NULL) | 0.00 | IES Lighting Handbook: The Standard Lighting Guide [34] |
Partial sensor | 600.00 | ||
Fully automated sensor | 1400.00 | ||
Lighting occupancy factor | Baseline (NULL) | 0.00 | https://www.homewyse.com/maintenance_costs/index.html; http://www.homedepot.com/, accessed on 5 April 2023 |
Partial sensor | 600.00 | ||
Fully automated sensor | 1400.00 | ||
Lighting constant illumination control factor | Baseline (NULL) | 0.00 | |
Partial sensor | 500.00 | ||
Fully automated sensor | 1000.00 | ||
Heating and Cooling Plants efficiencies (COPs) | Baseline HVAC | 0.00 | The R.S. Means. 2021. Facilities Maintenance & Repair Cost Data handbook [35] |
HVAC variation 2 | 1200.00 | ||
HVAC variation 3 | 2350.00 | ||
HVAC variation 4 | 4120.00 | ||
Heat recovery type | No heat recovery | 0.00 | The R.S. Means. 2009. Facilities Maintenance & Repair Cost Data. R.S. Means Company. [36] |
Heat exchange plates or pipes (0.65) | 2750.00 | ||
Two-elements-system (0.6) | 2300.00 | ||
Loading cold with air-conditioning (0.4) | 1800.00 | ||
Heat-pipes (0.6) | 2200.00 | ||
Slowly rotating or intermittent heat exchangers (0.7) | 3460.00 | ||
Exhaust air recirculation percentage | No exhaust air recirculation | 0.00 | |
Exhaust air recirculation 20% | 620.00 | ||
Exhaust air recirculation 40% | 1200.00 | ||
Exhaust air recirculation 60% | 1830.00 | ||
Building air leakage level | Minimum infiltration | 0.4 (Air flow m3/h per floor area at Q4Pa) | |
Maximum infiltration | 1.5 (Air flow m3/h per floor area at Q4Pa) | ||
DHW Generation System | Electric (0.75) | 0.00 | |
VR-Boiler (0.61) | 475.00 | ||
Gas Boiler, HR-Boiler (0.75) | 620.00 | ||
Co-Generation (0.9) | 1300.00 | ||
District Heating (0.9) | 450.00 | ||
Heat Pump (1.4) | 1800.00 | ||
Steam (0.61) | 530.00 | ||
Type of BEM system installed | Class D | 0.00 | |
Class C | 650.00 | ||
Class B | 2780.00 | ||
Class A | 4200.00 | ||
PV module Surface Area | Minimum # PV modules | 0 (PV module surface area, m2) | The R.S. Means (2010). Building Construction Cost Data. R.S. Means Company. [37] |
Maximum # PV modules | 35 (PV module surface area, m2) | ||
Solar Collector Surface Area | Minimum # Solar Col. | 0 (Solar collector surface area, m2) | |
Maximum # Solar Col. | 4 (Solar collector surface area, m2) | ||
Appliance | Energy-Star Baseline | 0.00 | http://www.dcd.com/, accessed on 5 April 2023 |
Energy-Star Top 10% | 1350.00 | ||
Energy-Star Top 5% | 2120.00 | ||
Lighting type | 100%CFL | 0.00 | https://www.energy.gov/eere/buildings/building-retrofit, accessed on 5 April 2023; The NREL database is also a good help: http://www.nrel.gov/ap/retrofits/group_listing.cfm/, accessed on 4 September 2022 |
LED&CFL combo | 3100.00 | ||
LED | 6700.00 | ||
Roof1 | Roof Baseline 1 | 0.00 | http://www.dcd.com/, accessed on 5 April 2023 |
Roof Improvement 2 | 600.00 | ||
Roof Improvement 3 | 2700.00 | ||
Opaque1 | Wall Baseline 1 | 0.00 | http://www.dcd.com/, accessed on 5 April 2023 |
Wall Improvement 2 | 3460.00 | ||
Wall Improvement 3 | 6840.00 | ||
Window1 | Window Baseline 1 | 0.00 | http://www.dcd.com/, accessed on 5 April 2023 |
Window Improvement 2 | 2140.00 | ||
Window Improvement 3 | 8700.00 |
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Li, W.; Sun, Z.; Makvandi, M.; Chen, Q.; Fu, J.; Gong, L.; Yuan, P.F. The Use of Normative Energy Calculation beyond the Optimum Retrofit Solutions in Primary Design: A Case Study of Existing Buildings on a Campus. Sustainability 2023, 15, 7094. https://doi.org/10.3390/su15097094
Li W, Sun Z, Makvandi M, Chen Q, Fu J, Gong L, Yuan PF. The Use of Normative Energy Calculation beyond the Optimum Retrofit Solutions in Primary Design: A Case Study of Existing Buildings on a Campus. Sustainability. 2023; 15(9):7094. https://doi.org/10.3390/su15097094
Chicago/Turabian StyleLi, Wenjing, Zhuoyang Sun, Mehdi Makvandi, Qingchang Chen, Jiayan Fu, Lei Gong, and Philip F. Yuan. 2023. "The Use of Normative Energy Calculation beyond the Optimum Retrofit Solutions in Primary Design: A Case Study of Existing Buildings on a Campus" Sustainability 15, no. 9: 7094. https://doi.org/10.3390/su15097094
APA StyleLi, W., Sun, Z., Makvandi, M., Chen, Q., Fu, J., Gong, L., & Yuan, P. F. (2023). The Use of Normative Energy Calculation beyond the Optimum Retrofit Solutions in Primary Design: A Case Study of Existing Buildings on a Campus. Sustainability, 15(9), 7094. https://doi.org/10.3390/su15097094