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Maximal heat transfer density in vertical morphing channels with natural convection

Publication ,  Journal Article
Da Silva, AK; Bejan, A; Lorente, S
Published in: Numerical Heat Transfer; Part A: Applications
January 16, 2004

In this article we show numerically that the entire flow geometry of a vertical diverging or converging channel with laminar natural convection can be optimized for maximal heat transfer rate density (total heat transfer rate per unit of flow system volume). The geometry is free to change in three ways: (1) the spacing between the walls, (2) the distribution of heating along the walls, and (3) the angle between the two walls. Numerical simulations cover the Rayleigh number range 105 ≤ RaH ≤ 107, where H is the channel height. Nonuniform wall heating is modeled as an isothermal patch of varying height H0 (≤H) on each wall, which is placed either at the bottom (entrance) end of the channel, or at the top (exit) end. The results confirm that the use of upper unheated sections enhances the chimney effect and the heat transfer. The new aspect is that the heat transfer rate density decreases because the unheated sections increase the total volume. It is shown that for maximal heat transfer rate density it is better to place the H0 sections at the channel entrance. It is also shown that the optimal angle between the two walls is approximately zero when RaH is large, i.e., for maximal heat transfer rate density the walls should be parallel or nearly parallel. Finally, the optimized spacing (1) developed in the presence of (2) and (3) as additional degrees of freedom is of the same order of magnitude as the optimal spacing reported earlier for parallel isothermal walls, i.e., in the absence of features (2) and (3). The robustness of the optimized flow architecture is discussed. Additional degrees of freedom and global objectives that may be incorporated in this constructal approach are the curvature of the facing walls and the mechanical strength and stiffness of the confining walls. © 2004, Taylor & Francis Group, LLC. All rights reserved.

Duke Scholars

Published In

Numerical Heat Transfer; Part A: Applications

DOI

EISSN

1521-0634

ISSN

1040-7782

Publication Date

January 16, 2004

Volume

45

Issue

2

Start / End Page

135 / 152

Related Subject Headings

  • Mechanical Engineering & Transports
  • 4901 Applied mathematics
  • 4012 Fluid mechanics and thermal engineering
  • 0913 Mechanical Engineering
  • 0905 Civil Engineering
  • 0102 Applied Mathematics
 

Citation

APA
Chicago
ICMJE
MLA
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Da Silva, A. K., Bejan, A., & Lorente, S. (2004). Maximal heat transfer density in vertical morphing channels with natural convection. Numerical Heat Transfer; Part A: Applications, 45(2), 135–152. https://doi.org/10.1080/10407780390236389
Da Silva, A. K., A. Bejan, and S. Lorente. “Maximal heat transfer density in vertical morphing channels with natural convection.” Numerical Heat Transfer; Part A: Applications 45, no. 2 (January 16, 2004): 135–52. https://doi.org/10.1080/10407780390236389.
Da Silva AK, Bejan A, Lorente S. Maximal heat transfer density in vertical morphing channels with natural convection. Numerical Heat Transfer; Part A: Applications. 2004 Jan 16;45(2):135–52.
Da Silva, A. K., et al. “Maximal heat transfer density in vertical morphing channels with natural convection.” Numerical Heat Transfer; Part A: Applications, vol. 45, no. 2, Jan. 2004, pp. 135–52. Scopus, doi:10.1080/10407780390236389.
Da Silva AK, Bejan A, Lorente S. Maximal heat transfer density in vertical morphing channels with natural convection. Numerical Heat Transfer; Part A: Applications. 2004 Jan 16;45(2):135–152.

Published In

Numerical Heat Transfer; Part A: Applications

DOI

EISSN

1521-0634

ISSN

1040-7782

Publication Date

January 16, 2004

Volume

45

Issue

2

Start / End Page

135 / 152

Related Subject Headings

  • Mechanical Engineering & Transports
  • 4901 Applied mathematics
  • 4012 Fluid mechanics and thermal engineering
  • 0913 Mechanical Engineering
  • 0905 Civil Engineering
  • 0102 Applied Mathematics