The Energy Saving Potential in an Office Building Using Louvers in Mid-Latitude Climate Conditions
<p>Research workflow [<a href="#B26-buildings-14-00512" class="html-bibr">26</a>].</p> "> Figure 2
<p>(<b>a</b>) Structure of louver and (<b>b</b>) definition of louver angles used in this study.</p> "> Figure 3
<p>Louver’s principle model.</p> "> Figure 4
<p>The test room was built for reference measurements.</p> "> Figure 5
<p>Distribution of sensor positions in the test room.</p> "> Figure 6
<p>The test room model is used for simulation in the DIALux software [<a href="#B24-buildings-14-00512" class="html-bibr">24</a>].</p> "> Figure 7
<p>(<b>a</b>) Test room in Rhino software and (<b>b</b>) the sun path of the designated simulation site [<a href="#B25-buildings-14-00512" class="html-bibr">25</a>].</p> "> Figure 8
<p>The results of the simulation against the measurements (S: simulation result; M: measurements result).</p> "> Figure 9
<p>Total energy that can be saved through the use cases of louver.</p> ">
Abstract
:1. Introduction
2. Methodology
- Using DIALux software 11.0, lighting conditions within a room using louvers and the amount of energy saved using the louver system [24].
- Using Rhino software 7, calculation of the energy required for heating and cooling in an office with and without the use of louvers [25]. The results were then analyzed to determine the energy-saving potential of the louver system. The research was carried out using a virtual model and a parametric approach on a simulation platform. The research workflow is depicted in Figure 1.
2.1. Model Specifications
2.1.1. Test Room Specifications
2.1.2. Louver
2.2. Measurement and Comparison Analysis
3. Simulation
3.1. Calculation and Simulation of Room Lighting
3.2. Thermal Energy Calculation and Simulation Using Rhino Software
4. Result
4.1. Compare the Results of Measuring Light Distribution in the Test Room and the Simulated Values
4.2. Calculation and Simulation Results of Lighting Energy
4.3. Calculation and Simulation Results of Cooling Energy
4.4. Total Energy Saved
5. Conclusions
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Article | Type | Louver Slat Angle | Comments |
---|---|---|---|
Muna Alsukkar et al. (2022) [2] | Horizontal | 0° to 60° and −40° to −10° | Free-glare indoor illumination |
Jìaeng Fang et al. (2022) [11] | Horizontal | 7° | Better daylighting luminous environment |
M. Alsukkar et al. (2022) [23] | Horizontal | 0° to 38° | Improve the daylighting performance of the split louver |
J.-H. Kim et al. (2022) [22] | Horizontal | 0° to 90° | Uniform indoor illuminance |
D. Uribe et al. (2019) [20] | Horizontal | 30°, 40°, 60° | Visual comfort |
Fujian Jiang (2019) [17] | Horizontal | 0°, 45°, 60° | Airflow for heat exchange |
F.F. Hernández et al. (2017) [21] | Horizontal and vertical | Vertical 0°, 30°, 60° −30°, −60° Horizontal 0° | Visual comfort and energy saving |
Component | Construction | Reflectance | Transmittance | Heat Transfer Coefficient (W/m2K) |
---|---|---|---|---|
Interior Walls | General Interior Wall | 0.5 | - | 2.58 |
Exterior Walls | General Exterior Wall | - | - | 0.46 |
Interior Ceiling | General Ceiling | 0.8 | - | 1.45 |
Interior Floor | General Floor | 0.2 | - | 1.45 |
Window | Clear Glass | 0.05 | 0.9 | 0.5 |
Louver slats | Coating Aluminum | 0.9 | - | 10 |
Data No. | Date and Time | Ev [lx] (10) | Ev [lx] (1) | Ev [lx] (2) | Ev [lx] (3) | Ev [lx] (4) | Ev [lx] (5) | Ev [lx] (6) | Ev [lx] (7) | Ev [lx] (8) | Ev [lx] (9) |
---|---|---|---|---|---|---|---|---|---|---|---|
1 | 30 November 2022 11:05:57 | 1.35 | 0.28 | 0.26 | 1.38 | 0.2 | 0.68 | 0.36 | 0.13 | 0.44 | 0.19 |
2 | 30 November 2022 11:06:27 | 5830 | 0.27 | 0.26 | 1.37 | 0.2 | 0.68 | 0.36 | 0.14 | 0.44 | 0.19 |
3 | 30 November 2022 11:06:57 | 12,530 | 0.28 | 0.26 | 1.4 | 0.2 | 0.68 | 0.37 | 0.12 | 0.45 | 0.19 |
4 | 30 November 2022 11:07:29 | 12,860 | 4710 | 8330 | 5840 | 2287 | 3200 | 2641 | 711 | 0.44 | 0.19 |
5 | 30 November 2022 11:07:58 | 14,240 | 4770 | 8370 | 5860 | 2321 | 3230 | 2659 | 944 | 1278 | 1134 |
6 | 30 November 2022 11:08:31 | 24,790 | 4830 | 8380 | 5860 | 2336 | 3240 | 2662 | 951 | 1286 | 1137 |
7 | 30 November 2022 11:09:01 | 39,700 | 4890 | 8430 | 5880 | 2354 | 3260 | 2673 | 959 | 1296 | 1143 |
8 | 30 November 2022 11:09:32 | 54,400 | 4960 | 8430 | 5880 | 2365 | 3270 | 2672 | 964 | 1302 | 1143 |
9 | 30 November 2022 11:10:02 | 65,700 | 5050 | 8440 | 5880 | 2377 | 3280 | 2676 | 970 | 1309 | 1147 |
10 | 30 November 2022 11:10:31 | 68,700 | 5090 | 8420 | 5850 | 2378 | 3270 | 2663 | 970 | 1309 | 1142 |
11 | 30 November 2022 11:11:01 | 68,700 | 5150 | 8420 | 5840 | 2388 | 3280 | 2663 | 974 | 1314 | 1143 |
12 | 30 November 2022 11:11:31 | 68,700 | 5170 | 8430 | 5840 | 2398 | 3280 | 2662 | 979 | 1321 | 1145 |
13 | 30 November 2022 11:12:01 | 69,600 | 5260 | 8520 | 5890 | 2432 | 3320 | 2686 | 992 | 1336 | 1156 |
14 | 30 November 2022 11:12:31 | 69,600 | 5280 | 8530 | 5900 | 2440 | 3330 | 2693 | 998 | 1344 | 1160 |
15 | 30 November 2022 11:13:01 | 69,700 | 5290 | 8530 | 5880 | 2448 | 3330 | 2682 | 997 | 1342 | 1155 |
16 | 30 November 2022 11:13:31 | 69,500 | 5280 | 8490 | 5850 | 2448 | 3320 | 2669 | 997 | 1342 | 1151 |
17 | 30 November 2022 11:14:01 | 69,300 | 5270 | 8460 | 5810 | 2449 | 3310 | 2654 | 996 | 1338 | 1145 |
18 | 30 November 2022 11:14:31 | 69,200 | 5270 | 8440 | 5800 | 2452 | 3310 | 2650 | 998 | 1340 | 1144 |
19 | 30 November 2022 11:15:01 | 69,500 | 5290 | 8530 | 5880 | 2448 | 3330 | 2682 | 997 | 1242 | 1355 |
20 | 30 November 2022 11:15:31 | 69,800 | 5290 | 8470 | 5800 | 2478 | 3330 | 2651 | 1007 | 1349 | 1145 |
21 | 30 November 2022 11:16:01 | 69,800 | 5290 | 8490 | 5800 | 2489 | 3340 | 2651 | 1012 | 1353 | 1147 |
22 | 30 November 2022 11:16:31 | 70,100 | 5310 | 8520 | 5820 | 2505 | 3350 | 2659 | 1019 | 1361 | 1150 |
23 | 30 November 2022 11:17:01 | 70,200 | 5300 | 8500 | 5800 | 2511 | 3350 | 2650 | 1020 | 1361 | 1148 |
24 | 30 November 2022 11:17:31 | 70,200 | 5310 | 8510 | 5800 | 2520 | 3360 | 2650 | 1024 | 1364 | 1148 |
25 | 30 November 2022 11:18:01 | 70,100 | 5310 | 8500 | 5790 | 2525 | 3360 | 2645 | 1026 | 1366 | 1145 |
26 | 30 November 2022 11:18:31 | 70,000 | 5320 | 8490 | 5770 | 2530 | 3350 | 2638 | 1029 | 1367 | 1144 |
27 | 30 November 2022 11:19:01 | 70,200 | 5350 | 8510 | 5770 | 2542 | 3360 | 2640 | 1035 | 1372 | 1145 |
28 | 30 November 2022 11:19:31 | 70,100 | 5360 | 8490 | 5760 | 2547 | 3360 | 2631 | 1035 | 1372 | 1141 |
29 | 30 November 2022 11:20:01 | 70,100 | 5380 | 8490 | 5750 | 2555 | 3370 | 2628 | 1039 | 1374 | 1141 |
30 | 30 November 2022 11:20:31 | 70,400 | 5410 | 8530 | 5760 | 2571 | 3380 | 2634 | 1045 | 1382 | 1144 |
31 | 30 November 2022 11:21:01 | 70,800 | 5420 | 8560 | 5780 | 2586 | 3390 | 2641 | 1051 | 1389 | 1148 |
32 | 30 November 2022 11:21:31 | 71,400 | 5460 | 8630 | 5820 | 2615 | 3420 | 2659 | 1062 | 1402 | 1156 |
33 | 30 November 2022 11:22:01 | 71,700 | 5460 | 8650 | 5820 | 2629 | 3440 | 2662 | 1069 | 1408 | 1158 |
34 | 30 November 2022 11:22:31 | 72,000 | 5470 | 8680 | 5830 | 2647 | 3450 | 2665 | 1075 | 1414 | 1160 |
35 | 30 November 2022 11:23:01 | 72,100 | 5470 | 8680 | 5820 | 2658 | 3450 | 2660 | 1079 | 1416 | 1159 |
36 | 30 November 2022 11:23:31 | 72,200 | 5460 | 8670 | 5800 | 2666 | 3450 | 2653 | 1082 | 1417 | 1156 |
37 | 30 November 2022 11:24:01 | 72,400 | 5470 | 8690 | 5800 | 2682 | 3460 | 2653 | 1089 | 1422 | 1157 |
38 | 30 November 2022 11:24:31 | 70,900 | 5350 | 8500 | 5660 | 2639 | 3390 | 2590 | 1073 | 1394 | 1132 |
39 | 30 November 2022 11:25:01 | 68,400 | 5140 | 8180 | 5440 | 2556 | 3260 | 2481 | 1036 | 1341 | 1083 |
40 | 30 November 2022 11:25:31 | 60,300 | 4520 | 7170 | 4750 | 2264 | 2860 | 2173 | 922 | 1184 | 953 |
41 | 30 November 2022 11:26:01 | 59,700 | 4480 | 7150 | 4730 | 2258 | 2840 | 2174 | 924 | 1188 | 957 |
Energy Requirement | Louver Opened 100% | Louver Opened 70% | Louver Opened 60% | Louver Opened 50% | Louver Opened 30% | |
---|---|---|---|---|---|---|
Lighting energy during a Year (kWh) | 95 | 15.8 | 19.3 | 23.6 | 24.4 | 36.3 |
Energy saving (kWh) | 0 | 79.2 | 75.7 | 71.4 | 70.6 | 58.7 |
Savings rate (%) | 0 | 83.3% | 79.7% | 75.2% | 74.3% | 61.8% |
Without Louver | Louver Opened 100% | Louver Opened 70% | Louver Opened 60% | Louver Opened 50% | Louver Opened 30% | |
---|---|---|---|---|---|---|
Cooling energy during a year (kWh) | 788 | 692 | 661 | 643 | 620 | 610 |
Energy saving (kWh) | 0 | 96 | 127 | 145 | 168 | 178 |
Savings rate (%) | 0 | 12.2% | 16.1% | 18.4% | 21.3% | 22.5% |
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Kieu, N.-M.; Ullah, I.; Park, J.; Bae, H.; Cho, M.; Lee, K.; Shin, S. The Energy Saving Potential in an Office Building Using Louvers in Mid-Latitude Climate Conditions. Buildings 2024, 14, 512. https://doi.org/10.3390/buildings14020512
Kieu N-M, Ullah I, Park J, Bae H, Cho M, Lee K, Shin S. The Energy Saving Potential in an Office Building Using Louvers in Mid-Latitude Climate Conditions. Buildings. 2024; 14(2):512. https://doi.org/10.3390/buildings14020512
Chicago/Turabian StyleKieu, Ngoc-Minh, Irfan Ullah, Jongbin Park, Hojune Bae, Meeryoung Cho, Keonwoo Lee, and Seoyong Shin. 2024. "The Energy Saving Potential in an Office Building Using Louvers in Mid-Latitude Climate Conditions" Buildings 14, no. 2: 512. https://doi.org/10.3390/buildings14020512
APA StyleKieu, N. -M., Ullah, I., Park, J., Bae, H., Cho, M., Lee, K., & Shin, S. (2024). The Energy Saving Potential in an Office Building Using Louvers in Mid-Latitude Climate Conditions. Buildings, 14(2), 512. https://doi.org/10.3390/buildings14020512