Assessing the Energy Performance and Retrofit Potential of the 1980–1990s’ Residential Building Stock in China’s Jiangsu Province: A Simulation-Based Study
Abstract
:1. Introduction
2. Materials and Methods
2.1. Bottom–Up Energy Modelling and Simulation
2.2. Building Carbon Emission Calculation Method
2.3. Retrofit Measure Selection
3. Results
3.1. Building Types and Baseline Model Development
3.1.1. Representative Building Types in Urban Areas of Jiangsu Province
3.1.2. Case Study and On-Site Investigation
3.1.3. Baseline Model Development
3.1.4. Baseline Model Calibration
3.2. Pre-Retrofit Energy Demand
3.3. Post-Retrofit Energy Demand: Single Retrofit Measures
3.4. Development of Retrofit Scenarios
Retrofit Measures and Scenario Development
- Three combinations of measures are selected based on the following regulations: JGJ 134-2010 Design Standard for Energy Efficiency of Residential Buildings in Hot Summer and Cold Winter Zone, China [92]; The Building Regulations 2010 L1B Conservation of fuel and power in existing dwellings, UK [99]; and Criteria for the Passive House, EnerPHit and PHI Low Energy Building Standard, Germany [100]. The China -based scenario assesses the potential of adapting the obsolete building types to the most current local standards. The UK and Germany-based scenarios assess the potential of implementing the best international practices and to evaluate their suitability in the local context. The thermal requirements of the two standards are not strictly complied with in this research; minor deviations were deemed tolerable to align the scenarios to the local specifications of materials and components. The three scenarios are named SCE_1_CN (China), SCE_2_UK (UK), and SCE_3_GER (Germany), respectively. Their configurations are summa-rised in Table 8.
- After the simulations, three additional combinations achieving the lowest total energy demand, heating demand, and cooling demand were selected regardless of retrofit costs, regulations, or other constraints. The scenarios were named SCE_4_BT (best total), SCE_5_BH (best heating), and SCE_6_BC (best cooling). Their configuration can vary depending on the building types, as shown in Table 9. It should be noted that for the Single-Danyuan Apartment, SCE_3_GER and SCE_4_BT coincide. That is, the optimal total energy demand reduction is achieved by meeting the German EnerPHit standard.
3.5. Post-Retrofit Energy Demand under Six Scenarios
3.5.1. Total Energy Demand Reduction
3.5.2. Heating and Cooling Demand Reduction
3.5.3. Carbon Emission Reduction
3.5.4. Thermal Comfort
3.5.5. Limitations
4. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
Abbreviations
ACH | Air Changes per Hour |
CABEE | China Association of Building Energy Efficiency |
CSWD | Chinese Standard Weather Data |
CV RMSE | Coefficient of Variation in the Root–Mean–Square Error |
HSCW zone | Hot summer–cold winter zone of China’s architecture climatic regions |
IAMs | Integrated Assessment Models |
IEA | International Energy Agency |
IPCC | Intergovernmental Panel on Climate Change |
RCP | Representative Concentration Pathways |
SWERA | Solar and Wind Energy Resource Assessment |
THUBERC | Tsinghua University Building Energy-saving Research Center |
TMY | Typical Meteorological Year |
Appendix A
Period | Electricity Use (KWh) | Gas Consumption (m3) |
---|---|---|
November, December | 280 | 16.94 |
January, February 2018 | 563 | 27.02 |
March, April | 339 | 27.02 |
May, June | 291 | 29.03 |
July, August | 300 | 25.09 |
September, October | 271 | 24.36 |
November, December | 356 | 28.73 |
January, February 2019 | 610 | 27.27 |
March, April | 334 | 35.27 |
May, June | 292 | 38.91 |
July, August | 324 | 22.91 |
September, October | 206 | 30.18 |
Appendix B
Summer | S-Low | S-Medium | S-High | Winter | S-Low | S-Medium | S-High | |
---|---|---|---|---|---|---|---|---|
0:00 | off | off | bedroom | 0:00 | off | off | off | |
1:00 | 1:00 | |||||||
2:00 | 2:00 | |||||||
3:00 | 3:00 | |||||||
4:00 | 4:00 | |||||||
5:00 | 5:00 | |||||||
6:00 | 6:00 | |||||||
7:00 | off | 7:00 | ||||||
8:00 | 8:00 | |||||||
9:00 | 9:00 | |||||||
10:00 | 10:00 | |||||||
11:00 | living room | 11:00 | ||||||
12:00 | 12:00 | |||||||
13:00 | Living room | 13:00 | ||||||
14:00 | 14:00 | |||||||
15:00 | 15:00 | |||||||
16:00 | off | 16:00 | ||||||
17:00 | 17:00 | living room | ||||||
18:00 | living room | 18:00 | ||||||
19:00 | living room | 19:00 | living room | |||||
20:00 | 20:00 | living room | ||||||
21:00 | 21:00 | |||||||
22:00 | bedroom | bedroom | bedroom | 22:00 | bedroom | bedroom | bedroom | |
23:00 | off | 23:00 | ||||||
0:00 | 0:00 | off | off | |||||
Totol hour | 4 | 10 | 20 | Totol hour | 4 | 5 | 8 |
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Retrofit Component | Code Name | Configuration | Properties |
---|---|---|---|
wall | pre-wall | no insulation (original) | U-value: 1.951 W/m2K |
WallSce_1 | EPS 30 mm | U-value: 0.695 W/m2K | |
WallSce_2 | EPS 60 mm | U-value: 0.440 W/m2K | |
WallSce_3 | EPS 90 mm | U-value: 0.322 W/m2K | |
roof | pre-roof | no insulation (original) | U-value: 3.231 W/m2K |
RoofSce_1 | XPS 30 mm | U-value: 0.598 W/m2K | |
RoofSce_2 | XPS 60 mm | U-value: 0.383 W/m2K | |
RoofSce_3 | XPS 90 mm | U-value: 0.282 W/m2K | |
window | Win Single | single glazing + Aluminum window frame without thermal break (original) | U-value: 5.9 W/m2K, SHGC: 0.75 |
Win Dbl | double glazing-Argon gas + Aluminum window frame with thermal break | U-value: 2.9 W/m2K, SHGC: 0.67 | |
Win_Dbl low-E | double low-E glazing-Argon gas + UPVC window frame | U-value: 2.0 W/m2K, SHGC: 0.62 | |
Win_Trp low-E | triple low-E glazing-Argon gas + UPVC window frame | U-value: 0.8 W/m2K, SHGC: 0.58 | |
air infiltration | 1.5 ACH | 1.5 ACH (original) | 1.5 ACH |
1.0 ACH | 1.0 ACH | 1.0 ACH | |
0.5 ACH | 0.5 ACH | 0.5 ACH | |
External wall façade reflectivity | Ref_0.4 | 0.4 (original) | 0.4 |
Ref_0.8 | 0.8 | 0.2 | |
south window overhang | none | none (original) | None |
0.5 m | 0.5 m | 0.5 m | |
staircase enclosure | semi-open | semi-open | semi-open |
closed | closed | closed |
Component | Thickness | U-Values [W/m2K] |
---|---|---|
Exterior wall | 0.24–0.28 m | 1.951 |
Roof | 0.18–0.22 m | 3.231 |
Partition wall | 0.24–0.28 m | 2.721 |
Internal floor | 0.15–0.22 | 2.753 |
Window | Single glass with timber or aluminium frames | 5.90 |
airtightness | 1.5 ACH | |
Shading devices | no shading or foldable rain shed | |
Staircase | Semi-open |
Building Property Information | |
---|---|
Construction Year | 1986 |
Floors | 6 |
Number of Staircase (Danyuan) | 4 |
Dwelling Unit per Danyuan | 2 |
Number of apartments | 48 |
Area per storey (sqm) | 470 |
Orientation | E-W |
Surface area to volume (S/V) ratio | 0.42 |
Window-to-wall ratio | 26.3% (north façade), 34.0% (south façade), 5.6% (east and west façades) |
Average storey height (m) | 2.9 m |
Central heating | No |
0:00 | 6:00 | 10:00 | 16:00 | 18:00 | 19:00 | 21:00 | 22:00 | 23:00 | 0:00 | Sum | |
---|---|---|---|---|---|---|---|---|---|---|---|
summer | low | Living room | Bedroom | 4 h | |||||||
high | Bedroom | Living room | Bedroom | 20 h | |||||||
winter | low | Living room | Bedroom | 4 h | |||||||
high | Living room | Bedroom | 8h |
South Jiangsu Region | Utility se Per Conditioned Floor Area [kWh/m2] | Total Site Energy per Total Building Area [kWh/m2] | |||
---|---|---|---|---|---|
Heating Demand | Cooling Demand | Total Energy Demand per Conditioned Area | |||
Multi-Danyuan apartment | Low-energy user | 39.62 | 23.70 | 100.81 | 74.08 |
high-energy user | 72.86 | 39.18 | 149.52 | 109.88 | |
Single-Danyuan apartment | Low-energy user | 37.30 | 29.40 | 91.70 | 72.80 |
high-energy user | 77.25 | 43.77 | 146.02 | 115.93 |
North Jiangsu Region | Utility se Per Conditioned Floor Area [kWh/m2] | Total Site Energy per Total Building Area [kWh/m2] | |||
---|---|---|---|---|---|
Heating Demand | Cooling Demand | Total Energy Demand per Conditioned Area | |||
Multi-Danyuan apartment | Low-energy user | 42.96 | 19.05 | 99.49 | 73.11 |
high-energy user | 85.3 | 32.73 | 155.52 | 114.28 | |
Single-Danyuan apartment | Low-energy user | 41.35 | 23.12 | 89.46 | 71.03 |
high-energy user | 92.7 | 35.68 | 153.37 | 121.77 |
Energy Demand Reduction (%) | Retrofit Configuration Code Name | Heating Reduction | Cooling Reduction | Total Reduction | |||
---|---|---|---|---|---|---|---|
Multi | Single | Multi | Single | Multi | Single | ||
Original | pre-retrofit | - | - | - | - | - | - |
wall | WallSce_1 | 7.48% | 10.60% | 4.59% | 7.38% | 4.85% | 7.82% |
WallSce_2 | 9.51% | 13.59% | 5.54% | 8.98% | 6.08% | 9.89% | |
WallSce_3 | 10.50% | 15.08% | 6.00% | 9.80% | 6.68% | 10.92% | |
roof | RoofSce_1 | 7.14% | 6.77% | 7.02% | 7.97% | 5.31% | 5.98% |
RoofSce_2 | 8.03% | 7.64% | 7.63% | 8.73% | 5.92% | 6.67% | |
RoofSce_3 | 8.48% | 8.08% | 7.94% | 9.09% | 6.22% | 7.00% | |
window | Win Dbl | 1.67% | 1.20% | 4.06% | 2.83% | 1.88% | 1.49% |
Win_Dbl low-E | 2.29% | 1.67% | 5.54% | 3.91% | 2.57% | 2.06% | |
Win_Trp low-E | 4.10% | 3.02% | 6.53% | 4.66% | 3.71% | 3.00% | |
air infiltration | 1.0 ACH | 8.83% | 8.78% | 6.18% | 6.79% | 5.92% | 6.68% |
0.5 ACH | 17.94% | 17.90% | 14.22% | 16.08% | 12.47% | 14.30% | |
external wall façade reflectivity | Ref_0.2 | 0.00% | 0.00% | 0.00% | 0.00% | 0.00% | 0.00% |
south window overhang | Ref_0.8 | −2.55% | −1.13% | 5.90% | 1.96% | 0.30% | 0.00% |
staircase enclosure | closed | 2.92% | 3.91% | −0.05% | 0.00% | 2.07% | 2.07% |
China Standard | UK Standard | Germany Standard | |
---|---|---|---|
Retrofit Component | SCE_1_CN | SCE_2_UK | SCE_3_GER |
Wall U-value [W/m2K] | 0.695 | 0.440 | 0.322 |
Roof U-value [W/m2K] | 0.598 | 0.383 | 0.282 |
Window U-value [W/m2K] | 2.9 | 2.0 | 0.8 |
Window SHGC | 0.67 | 0.62 | 0.58 |
Air infiltration | 1.5 ACH | 1.0 ACH | 0.5 ACH |
External wall façade reflectivity | 0.8 | 0.8 | 0.8 |
South window overhang | none | none | none |
Staircase enclosure | closed | closed | closed |
Retrofit Component | Multi-Danyuan Apartment | Single-Danyuan Apartment | ||||
---|---|---|---|---|---|---|
SCE_4_BT | SCE_5_BH | SCE_6_BC | SCE_4_BT | SCE_5_BH | SCE_6_BC | |
Wall U-value [W/m2K] | 0.322 | 0.322 | 0.322 | 0.322 | 0.322 | 0.322 |
Roof U-value [W/m2K] | 0.282 | 0.282 | 0.282 | 0.282 | 0.282 | 0.282 |
Window U-value [W/m2K] | 0.80 | 0.80 | 0.80 | 0.80 | 0.80 | 0.80 |
Window SHGC | 0.58 | 0.58 | 0.58 | 0.58 | 0.58 | 0.58 |
Air infiltration | 0.5 ACH | 0.5 ACH | 0.5 ACH | 0.5 ACH | 0.5 ACH | 0.5 ACH |
External wall façade reflectivity | 0.8 | 0.4 | 0.8 | 0.8 | 0.4 | 0.8 |
South window overhang | 0.5 m | none | 0.5 m | none | none | 0.5 m |
Staircase enclosure | closed | closed | semi-open | closed | closed | closed |
Material Prices Estimation (RMB/m2) | Multi-Danyuan Apartment | Single-Danyuan Apartment |
---|---|---|
SCE_1_CN | 1095.10 | 1095.10 |
SCE_2_UK | 1198.55 | 1198.55 |
SCE_3_GER | 1427.00 | 1427.00 |
SCE_4_BT | 1470.00 | 1427.00 |
SCE_5_BH | 1427.00 | 1427.00 |
SCE_6_BC | 1220.00 | 1470.00 |
Total Site Energy per Total Building Area [kWh/m2] | ||||
---|---|---|---|---|
Multi-Danyuan Apartment | Low-Energy | High-Energy | ||
South | North | South | North | |
Pre-retrofit | 74.08 | 73.11 | 109.88 | 114.28 |
SCE_1_CN | 65.63 | 64.70 | 84.36 | 84.93 |
SCE_2_UK | 59.44 | 58.77 | 70.07 | 69.78 |
SCE_3_GER | 57.22 | 56.34 | 65.26 | 64.37 |
SCE_4_BT | 56.85 | 56.00 | 64.62 | 63.77 |
SCE_5_BH | 57.35 | 56.47 | 65.47 | 64.60 |
SCE_6_BC | 59.07 | 58.57 | 69.15 | 69.25 |
Total Site Energy per Total Building Area [kWh/m2] | ||||
---|---|---|---|---|
Single-Danyuan Apartment | Low-Energy | High-Energy | ||
South | North | South | North | |
Pre-retrofit | 72.8 | 71.03 | 115.93 | 121.77 |
SCE_1_CN | 61.35 | 59.82 | 82.4 | 83.67 |
SCE_2_UK | 52.67 | 51.98 | 63.76 | 64.15 |
SCE_3_GER | 49.96 | 49.10 | 58.18 | 57.95 |
SCE_4_BT | 50.17 | 49.33 | 58.53 | 58.33 |
SCE_5_BH | 49.97 | 49.14 | 58.18 | 58.02 |
SCE_6_BC | 72.8 | 71.03 | 115.93 | 121.77 |
Pre-Retrofit | SCE_1_CN | SCE_2_UK | SCE_3_GER | SCE_4_BT | SCE_5_BH | SCE_6_BC | |
---|---|---|---|---|---|---|---|
Multi-Danyuan Apartment South | 1254 (100%) | 1139 (−9.2%) | 884 (−29.5%) | 706 (−43.7%) | 896 (−28.5%) | 834 (−33.5%) | 1130 (−9.9%) |
Multi-Danyuan Apartment North | 1141 (100%) | 1022 (−10.4%) | 697 (−38.9%) | 505 (−55.7%) | 760 (−33.3%) | 587 (−48.5%) | 1021 (−10.4%) |
Single-Danyuan Apartment South | 1486 (100%) | 1351 (−9.1%) | 1144 (−23.0%) | 1000 (−32.7%) | 1000 (−32.7%) | 937 (−36.9%) | 1104 (−25.7%) |
Single-Danyuan Apartment North | 1268 (100%) | 1220 (−3.8%) | 1008 (−20.5%) | 827 (−34.8%) | 827 (−34.8%) | 750 (−40.6%) | 984 (−22.4%) |
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Chen, X.; Cimillo, M.; Chow, D.; Chen, B. Assessing the Energy Performance and Retrofit Potential of the 1980–1990s’ Residential Building Stock in China’s Jiangsu Province: A Simulation-Based Study. Energies 2024, 17, 1260. https://doi.org/10.3390/en17051260
Chen X, Cimillo M, Chow D, Chen B. Assessing the Energy Performance and Retrofit Potential of the 1980–1990s’ Residential Building Stock in China’s Jiangsu Province: A Simulation-Based Study. Energies. 2024; 17(5):1260. https://doi.org/10.3390/en17051260
Chicago/Turabian StyleChen, Xi, Marco Cimillo, David Chow, and Bing Chen. 2024. "Assessing the Energy Performance and Retrofit Potential of the 1980–1990s’ Residential Building Stock in China’s Jiangsu Province: A Simulation-Based Study" Energies 17, no. 5: 1260. https://doi.org/10.3390/en17051260
APA StyleChen, X., Cimillo, M., Chow, D., & Chen, B. (2024). Assessing the Energy Performance and Retrofit Potential of the 1980–1990s’ Residential Building Stock in China’s Jiangsu Province: A Simulation-Based Study. Energies, 17(5), 1260. https://doi.org/10.3390/en17051260