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Journal Articles
Publisher: ASME
Article Type: Research-Article
J. Heat Mass Transfer. May 2025, 147(5): 051802.
Paper No: HT-24-1279
Published Online: February 6, 2025
Journal Articles
Publisher: ASME
Article Type: Research-Article
J. Heat Mass Transfer. May 2025, 147(5): 052401.
Paper No: HT-24-1289
Published Online: February 6, 2025
Journal Articles
Publisher: ASME
Article Type: Research-Article
J. Heat Mass Transfer. May 2025, 147(5): 051602.
Paper No: HT-24-1241
Published Online: February 6, 2025
Journal Articles
Publisher: ASME
Article Type: Research-Article
J. Heat Mass Transfer. May 2025, 147(5): 051501.
Paper No: HT-24-1309
Published Online: February 6, 2025
Journal Articles
Publisher: ASME
Article Type: Research-Article
J. Heat Mass Transfer. May 2025, 147(5): 051801.
Paper No: HT-24-1213
Published Online: February 6, 2025
Journal Articles
Publisher: ASME
Article Type: Research-Article
J. Heat Mass Transfer. June 2025, 147(6): 062702.
Paper No: HT-24-1328
Published Online: February 6, 2025
Journal Articles
Publisher: ASME
Article Type: Research-Article
J. Heat Mass Transfer. May 2025, 147(5): 051201.
Paper No: HT-24-1162
Published Online: February 6, 2025
Journal Articles
Publisher: ASME
Article Type: Research-Article
J. Heat Mass Transfer. June 2025, 147(6): 061201.
Paper No: HT-24-1319
Published Online: February 6, 2025
Journal Articles
Publisher: ASME
Article Type: Research-Article
J. Heat Mass Transfer. June 2025, 147(6): 062701.
Paper No: HT-24-1293
Published Online: February 6, 2025
Journal Articles
Publisher: ASME
Article Type: Research-Article
J. Heat Mass Transfer. June 2025, 147(6): 061801.
Paper No: HT-24-1305
Published Online: February 6, 2025
Journal Articles
Yijie Zhou, Dina Hertog-Raz, Saqlain Raza, Josh Transtamar, Benjamin Abarca, Yangyang Wang, Jun Liu, Yanfei Xu
Publisher: ASME
Article Type: Research-Article
J. Heat Mass Transfer. March 2025, 147(3): 031402.
Paper No: HT-24-1269
Published Online: February 6, 2025
Topics:
Composite materials,
Fillers (Materials),
Graphite,
Polymer composites,
Polymers,
Thermal conductivity,
Interfacial thermal resistance,
Atoms
Includes: Supplementary data
Image
in An Exact Solution Based on a Three-Energy Equation Model for Gaseous Transpiration Cooling Through a Bi-Disperse Porous Medium
> ASME Journal of Heat and Mass Transfer
Published Online: February 6, 2025
Fig. 1 Transpiration cooling using a bi-disperse porous medium More about this image found in Transpiration cooling using a bi-disperse porous medium
Image
in An Exact Solution Based on a Three-Energy Equation Model for Gaseous Transpiration Cooling Through a Bi-Disperse Porous Medium
> ASME Journal of Heat and Mass Transfer
Published Online: February 6, 2025
Fig. 2 Verification of the present solution for the case of monodisperse porous media: ( a ) fluid and solid temperature difference ratio on the hot wall side and ( b ) solid temperature on the hot wall side More about this image found in Verification of the present solution for the case of monodisperse porous me...
Image
in An Exact Solution Based on a Three-Energy Equation Model for Gaseous Transpiration Cooling Through a Bi-Disperse Porous Medium
> ASME Journal of Heat and Mass Transfer
Published Online: February 6, 2025
Fig. 3 Temperature distributions across the bi-disperse porous wall closely packed with small and large particles ( ε 2 = ε 1 = 0.36 , D 2 = 0.002 m , D 1 = 0.0004 m , L = 0.01 m ) as compared with those of monodispers... More about this image found in Temperature distributions across the bi-disperse porous wall closely packed...
Image
in An Exact Solution Based on a Three-Energy Equation Model for Gaseous Transpiration Cooling Through a Bi-Disperse Porous Medium
> ASME Journal of Heat and Mass Transfer
Published Online: February 6, 2025
Fig. 4 Overall cooling efficiency of bi-disperse porous wall closely packed with small and large particles ( ε 2 = ε 1 = 0.36 , D 2 = 0.002 m , L = 0.01 m ) as compared with that of monodisperse porous wall ( ε 2 = 0.36 ... More about this image found in Overall cooling efficiency of bi-disperse porous wall closely packed with s...
Image
in An Exact Solution Based on a Three-Energy Equation Model for Gaseous Transpiration Cooling Through a Bi-Disperse Porous Medium
> ASME Journal of Heat and Mass Transfer
Published Online: February 6, 2025
Fig. 5 Effect of ε 1 on the overall cooling efficiency of bi-disperse porous wall filled with small and large particles ( ε 2 = 0.36 , D 2 = 0.002 m , D 1 / D 2 = 0.2): ( a ) η against P e L ... More about this image found in Effect of ε 1 on the overall cooling efficiency of bi-disper...
Image
in An Exact Solution Based on a Three-Energy Equation Model for Gaseous Transpiration Cooling Through a Bi-Disperse Porous Medium
> ASME Journal of Heat and Mass Transfer
Published Online: February 6, 2025
Fig. 6 Effect of ε 1 on Nusselt number of bi-disperse porous wall filled with small and large particles ( ε 2 = 0.36 , D 2 = 0.002 m , D 1 / D 2 = 0.2) More about this image found in Effect of ε 1 on Nusselt number of bi-disperse porous wall f...
Image
in An Exact Solution Based on a Three-Energy Equation Model for Gaseous Transpiration Cooling Through a Bi-Disperse Porous Medium
> ASME Journal of Heat and Mass Transfer
Published Online: February 6, 2025
Fig. 7 Suitable range of the Peclet number, under which the transpiration cooling should be operated ( ε 2 = ε 1 = 0.36 , D 2 = 0.002 m , D 1 / D 2 = 0.2) More about this image found in Suitable range of the Peclet number, under which the transpiration cooling ...
Image
in Numerical Simulation of Phase Change Dual-Phase-Lag Bioheat Model With Nanocryosurgery Using Radial Basis Function Meshfree Approach
> ASME Journal of Heat and Mass Transfer
Published Online: February 6, 2025
Fig. 1 Domain with uniform internal nodes (Color version online.) More about this image found in Domain with uniform internal nodes (Color version online.)
Image
in Numerical Simulation of Phase Change Dual-Phase-Lag Bioheat Model With Nanocryosurgery Using Radial Basis Function Meshfree Approach
> ASME Journal of Heat and Mass Transfer
Published Online: February 6, 2025
Fig. 2 Schematic representation of the cryofreezing process More about this image found in Schematic representation of the cryofreezing process
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