### Abstract

We study the effects of particle-turbulence interactions on heat transfer in a particleladen turbulent channel flow using an Eulerian-Lagrangian simulation approach, with direct numerical simulation (DNS) for turbulence and Lagrangian tracking for particles. A two-way coupling model is employed in which the momentum and energy exchange between the discrete particles and the continuous fluid phase is fully taken into account. Our study focuses on the modulations of the temperature field and heat transfer process by inertial particles with different particle momentum Stokes numbers (St), which in a combination of the particle-to-fluid specific heat ratio and the Prandtl number results in different particle heat Stokes numbers. It is found that as St increases, while the turbulent heat flux decreases due to the suppression of wall-normal turbulence velocity fluctuation, the particle feedback heat flux increases significantly and results in an increase in the total heat flux. The particle thermal feedback effect is illustrated using the instantaneous structures and statistics of the flow and temperature fields. The mechanisms of heat transfer modulation by inertial particles are investigated in detail. The budget of turbulent heat flux is examined. Moreover, by taking advantage of the ability of numerical simulation to address different momentum and heat processes separately, we investigate in detail the two processes of particles affecting heat transfer for the first time, namely the direct effect of particle thermal feedback to the fluid (i.e., heat feedback) and the indirect effect of the modulation of turbulent velocity field induced by the particles (i.e., momentum feedback). It is found that the contribution of heat transfer from turbulent convection is reduced by both heat and momentum feedback due to the decrease of the turbulent heat flux. The contribution of heat transfer from particle transport effects is barely influenced by the momentum feedback, even if St is large and is mainly affected by the heat feedback. Our results indicate that both heat and momentum feedback are important when the particle inertia is large, suggesting that both feedback processes need to be taken into account in computation and modeling.

Original language | English (US) |
---|---|

Article number | 112003 |

Journal | Journal of Heat Transfer |

Volume | 140 |

Issue number | 11 |

DOIs | |

State | Published - Nov 1 2018 |

### Fingerprint

### Keywords

- Direct Numerical Simulation
- Heat Feedback
- Heat Transfer
- Lagrangian Tracking Approach
- Momentum Feedback
- Particle-Laden Flow

### Cite this

*Journal of Heat Transfer*,

*140*(11), [112003]. https://doi.org/10.1115/1.4040347

**Heat transfer modulation by inertial particles in particle-laden turbulent channel flow.** / Liu, Caixi; Tang, Shuai; Dong, Yuhong; Shen, Lian.

Research output: Contribution to journal › Article

*Journal of Heat Transfer*, vol. 140, no. 11, 112003. https://doi.org/10.1115/1.4040347

}

TY - JOUR

T1 - Heat transfer modulation by inertial particles in particle-laden turbulent channel flow

AU - Liu, Caixi

AU - Tang, Shuai

AU - Dong, Yuhong

AU - Shen, Lian

PY - 2018/11/1

Y1 - 2018/11/1

N2 - We study the effects of particle-turbulence interactions on heat transfer in a particleladen turbulent channel flow using an Eulerian-Lagrangian simulation approach, with direct numerical simulation (DNS) for turbulence and Lagrangian tracking for particles. A two-way coupling model is employed in which the momentum and energy exchange between the discrete particles and the continuous fluid phase is fully taken into account. Our study focuses on the modulations of the temperature field and heat transfer process by inertial particles with different particle momentum Stokes numbers (St), which in a combination of the particle-to-fluid specific heat ratio and the Prandtl number results in different particle heat Stokes numbers. It is found that as St increases, while the turbulent heat flux decreases due to the suppression of wall-normal turbulence velocity fluctuation, the particle feedback heat flux increases significantly and results in an increase in the total heat flux. The particle thermal feedback effect is illustrated using the instantaneous structures and statistics of the flow and temperature fields. The mechanisms of heat transfer modulation by inertial particles are investigated in detail. The budget of turbulent heat flux is examined. Moreover, by taking advantage of the ability of numerical simulation to address different momentum and heat processes separately, we investigate in detail the two processes of particles affecting heat transfer for the first time, namely the direct effect of particle thermal feedback to the fluid (i.e., heat feedback) and the indirect effect of the modulation of turbulent velocity field induced by the particles (i.e., momentum feedback). It is found that the contribution of heat transfer from turbulent convection is reduced by both heat and momentum feedback due to the decrease of the turbulent heat flux. The contribution of heat transfer from particle transport effects is barely influenced by the momentum feedback, even if St is large and is mainly affected by the heat feedback. Our results indicate that both heat and momentum feedback are important when the particle inertia is large, suggesting that both feedback processes need to be taken into account in computation and modeling.

AB - We study the effects of particle-turbulence interactions on heat transfer in a particleladen turbulent channel flow using an Eulerian-Lagrangian simulation approach, with direct numerical simulation (DNS) for turbulence and Lagrangian tracking for particles. A two-way coupling model is employed in which the momentum and energy exchange between the discrete particles and the continuous fluid phase is fully taken into account. Our study focuses on the modulations of the temperature field and heat transfer process by inertial particles with different particle momentum Stokes numbers (St), which in a combination of the particle-to-fluid specific heat ratio and the Prandtl number results in different particle heat Stokes numbers. It is found that as St increases, while the turbulent heat flux decreases due to the suppression of wall-normal turbulence velocity fluctuation, the particle feedback heat flux increases significantly and results in an increase in the total heat flux. The particle thermal feedback effect is illustrated using the instantaneous structures and statistics of the flow and temperature fields. The mechanisms of heat transfer modulation by inertial particles are investigated in detail. The budget of turbulent heat flux is examined. Moreover, by taking advantage of the ability of numerical simulation to address different momentum and heat processes separately, we investigate in detail the two processes of particles affecting heat transfer for the first time, namely the direct effect of particle thermal feedback to the fluid (i.e., heat feedback) and the indirect effect of the modulation of turbulent velocity field induced by the particles (i.e., momentum feedback). It is found that the contribution of heat transfer from turbulent convection is reduced by both heat and momentum feedback due to the decrease of the turbulent heat flux. The contribution of heat transfer from particle transport effects is barely influenced by the momentum feedback, even if St is large and is mainly affected by the heat feedback. Our results indicate that both heat and momentum feedback are important when the particle inertia is large, suggesting that both feedback processes need to be taken into account in computation and modeling.

KW - Direct Numerical Simulation

KW - Heat Feedback

KW - Heat Transfer

KW - Lagrangian Tracking Approach

KW - Momentum Feedback

KW - Particle-Laden Flow

UR - http://www.scopus.com/inward/record.url?scp=85053183806&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85053183806&partnerID=8YFLogxK

U2 - 10.1115/1.4040347

DO - 10.1115/1.4040347

M3 - Article

AN - SCOPUS:85053183806

VL - 140

JO - Journal of Heat Transfer

JF - Journal of Heat Transfer

SN - 0022-1481

IS - 11

M1 - 112003

ER -