Acta Aeronautica et Astronautica Sinica ›› 2025, Vol. 46 ›› Issue (5): 531185.doi: 10.7527/S1000-6893.2024.31185
• Fluid Mechanics and Flight Mechanics • Previous Articles
Hongqiang LYU(
), Tiancheng TANG, Chenyu BAO
CJA
Received:2024-09-11
Revised:2024-09-18
Accepted:2024-09-29
Online:2024-10-16
Published:2024-10-15
Contact:
Hongqiang LYU
E-mail:hongqiang.lu@nuaa.edu.cn
Supported by:CLC Number:
Hongqiang LYU, Tiancheng TANG, Chenyu BAO. Numerical simulation of fluid-solid conjugate natural convection heat transfer based on SPH method[J]. Acta Aeronautica et Astronautica Sinica, 2025, 46(5): 531185.
Fig.1
Example of natural convection in a closed square cavity
Fig.2
Temperature fields of self-heating convection in a closed square cavity with different particle numbers
Fig.3
Temperature fields of self-heating convection in a closed square cavity with different Ra
Fig.4
Streamlines of self-heating convection in a closed square cavity with different Ra
Table 1
Comparison of average Nusselt numbers at heated wall of self-heating convection in a closed square cavity
| D’Orazio等[ | de Vahl Davis[ | Barakos等[ | 本文结果 | |
|---|---|---|---|---|
| 1.117 | 1.118 | 1.114 | 1.117 | |
| 2.235 | 2.243 | 2.245 | 2.252 | |
| 4.504 | 4.519 | 4.510 | 4.518 |
Fig.5
Example of natural convection in horizontal annular
Fig.6
Comparison of temperature fields of self-heating convection in horizontal annular(R=2.6, ε=0, φ=0, Ra=4.7×104, Pr=0.706)
Fig.7
Comparison of radial temperature distribution for different angles in horizontal annular(R=2.6, ε=0, φ=0, Ra=4.7×104, Pr=0.706)
Fig.8
Example of natural convection in a closed square cavity with a solid block
Fig.9
Comparison of temperature fields of self-heating convection in a closed square cavity with a solid block (k=0.2)
Fig.10
Comparison of temperature fields of self-heating convection in a closed square cavity with a solid block (k=5.0)
Table 2
Comparison of average Nusselt numbers at heated wall of self-heating convection in a closed square cavity with a solid block
| House等[ | Braga和de Lemos[ | Merrikh和Lage[ | 本文 | |
|---|---|---|---|---|
| 0.2 | 4.624 | 4.667 | 4.605 | 4.638 |
| 5.0 | 4.324 | 4.375 | 4.280 | 4.283 |
Fig.11
Example of natural convection in a closed square cavity with 16 square solid blocks
Table 3
Comparison of average Nusselt numbers at heated wall of self-heating convection in a closed square cavity with 16 square solid blocks
| Merrikh和Lage[ | Raji等[ | Karani和Huber[ | Lu等[ | 本文 | |
|---|---|---|---|---|---|
| 0.1 | 0.813 | 0.785 | 0.796 9 | 0.814 3 | 0.804 0 |
| 1.0 | 1.233 | 1.193 | 1.185 0 | 1.249 1 | 1.218 1 |
| 10.0 | 2.030 | 2.066 | 2.031 0 | 2.056 6 | 2.014 4 |
| 100.0 | 2.313 | 2.394 | 2.450 6 | 2.335 1 | 2.414 5 |
Fig.12
Comparison of temperature fields of self-heating convection in a closed square cavity with 16 square solid blocks (Ra=105, Pr=1, k=1.0)
Fig.13
Example of natural convection in a closed square cavity with 16 circle solid blocks
Table 4
Comparison of average Nusselt numbers at heated wall of self-heating convection in a closed square cavity with 16 circle solid blocks
| FVM[ | TLBM[ | 本文 | |
|---|---|---|---|
| 0.1 | 0.838 6 | 0.819 8 | 0.813 9 |
| 1.0 | 1.246 7 | 1.239 8 | 1.212 4 |
| 10.0 | 2.011 6 | 2.026 2 | 2.038 4 |
| 100.0 | 2.257 7 | 2.273 7 | 2.259 9 |
Fig.14
Comparison of temperature fields of self-heating convection in a closed square cavity with 16 circle solid blocks (Ra=105, Pr=0.7, k=0.1)
Fig.15
Example of natural convection in a closed square cavity with a solid body with heat sources
Fig.16
Comparison of temperature fields of self-heating convection in a closed square cavity with a solid body with heat sources (Ra=103, Pr=0.011 2, k=1.71, ΔT*=2.5)
Fig.17
Comparison of temperature fields of self-heating convection in a closed square cavity with a solid body with heat sources (Ra=103, Pr=0.011 2, k=1.71, ΔT*=50.0)
Fig.18
Comparison of temperature fields of self-heating convection in a closed square cavity with a solid body with heat sources (Ra=104, Pr=0.011 2, k=1.71, ΔT*=2.5)
Table 5
Comparison of average Nusselt numbers(Nuh and Nuc) at wall of self-heating convection in a closed square cavity with a solid body with heat sources
| Ha和Jung[ | 本文 | Ha和Jung[ | 本文 | ||
|---|---|---|---|---|---|
| 2.5 | -0.077 | -0.076 | 2.238 | 2.243 | |
| 25.0 | -11.473 | -11.492 | 6.759 | 6.711 | |
| 2.5 | 0.155 | 0.154 | 3.283 | 3.302 | |
| 25.0 | -11.101 | -11.097 | 7.649 | 7.698 | |
Fig.19
Schematic diagram of heat sink structure
Fig.20
Schematic diagram of computational domain of heat sink
Fig.21
Temperature fields at position y=0 at time t=10(k=10.0, ΔT*=1)
Fig.22
Temperature fields at position x=2.5 when Re=102 (t=10, ΔT*=1)
Fig.23
Temperature fields at position x=2.5 when Re=103 (t=10, ΔT*=1)
Table 6
Maximum internal temperature of heat sink structure under different physical parameters at time t=10 when Re=102
| 6.306 | 27.070 | 234.708 | |
| 5.299 | 18.627 | 151.901 | |
| 2.723 | 7.949 | 60.201 | |
| 1.768 | 4.464 | 31.564 |
Table 7
Maximum internal temperature of heat sink structure under different physical parameters at time t=10 when Re=103
| 6.306 | 27.070 | 234.708 | |
| 5.280 | 18.608 | 151.882 | |
| 2.416 | 7.587 | 59.202 | |
| 1.356 | 3.881 | 29.130 |
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