Heat Transfer Enhancement in a Novel Annular Tube with Outer Straight and Inner Twisted Oval Tubes
Abstract
:1. Introduction
2. Physical Model and Numerical Method
- (a)
- A uniform velocity uin and constant temperature (Tin = 293K) are adopted at the inlet.
- (b)
- The turbulence intensity (I) of the inlet is obtained by I = 0.16Re−1/8.
- (c)
- All of the tube walls are no-slip.
- (d)
- A constant temperature (Tw = 363K) and adiabatic condition are adopted at the inner wall and outer wall, respectively.
- (e)
- Outlet: an outflow boundary condition is applied, i.e., .
3. Results
3.1. Secondary Flow in the Annulus
3.2. Temperature in the Annular Space
3.3. Effects of s and e on Nu and f
3.4. Effects of s and e on JF
3.5. Correlations
4. Conclusions
- (1)
- The fluid mixing in the annulus is obviously improved by the inner twisted oval tube.
- (2)
- Nu and f increase as both the aspect ratio and twist ratio decrease. The largest relative increments of Nu and f are 35% and 13% between different aspect ratios, and 26% and 18% between different twist ratios.
- (3)
- The inner twisted oval tube yields 116% and 46% increases in Nu and f, respectively, compared with the inner straight tube.
- (4)
- The thermal performance enhancement is more significant in the laminar regime. The largest JF = 1.9 is obtained for aspect ratio 0.4 and twist ratio 10 at Re = 3000, which is the largest Re in the laminar regime.
- (5)
- The deviations for Nu and f of the correlations are within ±5% and ±4%, respectively.
Author Contributions
Funding
Conflicts of Interest
Nomenclature
ao | long-axis length of outer tube, m |
ai | long-axis length of inner tube, m |
A | cross-sectional area, m2 |
bo | short-axis length of outer tube, m |
bi | short-axis length of inner tube, m |
Dh | hydraulic diameter, m |
e | aspect ratio |
f | friction factor |
Gk | turbulent kinetic energy due to mean velocity gradient, J/kg |
hi | heat transfer coefficient, W/(m2 K) |
JF | thermal performance factor |
k | turbulent kinetic energy, J/kg |
L | length of the annular domain, m |
LP | wetted perimeter, m |
Nu | Nusselt number |
Δp | pressure loss, Pa |
P | length of twisted pitch, m |
q | wall heat flux, W/m2 |
Re | Reynolds number |
s | twist ratio |
S | fin surface area, m2 |
T | temperature, K |
Ts | bulk temperature, K |
u, v, w | components of velocity vector, m/s |
X | non-dimensional distance |
x, y, z | coordinates, m |
Greek symbols | |
ε | turbulent dissipation rate, J/(kg s) |
λ | thermal conductivity, W/(m K) |
μ | dynamic viscosity, kg/(m s) |
ρ | density, kg/m3 |
Subscripts | |
0 | straight inner and outer oval tubes |
in | inlet |
t | turbulent |
w | wall surface |
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Calculation Model | Laminar, Re = 1000 | RNG k–ε, Re = 11,000 | ||
---|---|---|---|---|
fRe | Nu | fRe | Nu | |
Experiment [24] | 22.7 | 4.41 | 87.4 | 43.31 |
Present | 21.45 | 4.01 | 97.39 | 38.67 |
Relative error | 5.5% | 9.1% | 11.4% | 10.7% |
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Luo, C.; Song, K.; Tagawa, T.; Liu, T. Heat Transfer Enhancement in a Novel Annular Tube with Outer Straight and Inner Twisted Oval Tubes. Symmetry 2020, 12, 1213. https://doi.org/10.3390/sym12081213
Luo C, Song K, Tagawa T, Liu T. Heat Transfer Enhancement in a Novel Annular Tube with Outer Straight and Inner Twisted Oval Tubes. Symmetry. 2020; 12(8):1213. https://doi.org/10.3390/sym12081213
Chicago/Turabian StyleLuo, Chao, KeWei Song, Toshio Tagawa, and TengFei Liu. 2020. "Heat Transfer Enhancement in a Novel Annular Tube with Outer Straight and Inner Twisted Oval Tubes" Symmetry 12, no. 8: 1213. https://doi.org/10.3390/sym12081213
APA StyleLuo, C., Song, K., Tagawa, T., & Liu, T. (2020). Heat Transfer Enhancement in a Novel Annular Tube with Outer Straight and Inner Twisted Oval Tubes. Symmetry, 12(8), 1213. https://doi.org/10.3390/sym12081213