Single-bubble dynamics in pool boiling of one-component fluids

Xu, Xinpeng; Qian, Tiezheng

doi:10.1103/physreve.89.063002

Cited by 22 publications

(14 citation statements)

References 54 publications

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“…90 Boiling heat transfer is used in a wide field of applications: from cooking activities in everyday life to various energy conversion and heat exchange systems as well as cooling of high-energy-density power/electronic devices [357,358], such as boiling water reactors in nuclear power plants. While boiling phenomena can be encountered in daily life, the boiling processes are extremely complex and elusive because many physical components are involved and interrelated, such as the nucleation, growth, departure, and coalescence of vapor bubbles, the transport of latent heat, and the instability of liquid-vapor interfaces [290].…”

Section: Fig 21 Simulation Of the Collision Between Two Droplets Anmentioning

confidence: 99%

Lattice Boltzmann methods for multiphase flow and phase-change heat transfer

Luo

Kang

et al. 2016

Progress in Energy and Combustion Science

777

373

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Over the past few decades, tremendous progress has been made in the development of particle-based discrete simulation methods versus the conventional continuum-based methods. In particular, the lattice Boltzmann (LB) method has evolved from a theoretical novelty to a ubiquitous, versatile and powerful computational methodology for both fundamental research and engineering applications. It is a kinetic-based mesoscopic approach that bridges the microscales and macroscales, which offers distinctive advantages in simulation fidelity and computational efficiency. Applications of the LB method are now found in a wide range of disciplines including physics, chemistry, materials, biomedicine and various branches of engineering. The present work provides a comprehensive review of the LB method for thermofluids and energy applications, focusing on multiphase flows, thermal flows and thermal multiphase flows with phase change. The review first covers the theoretical framework of the LB method, revealing certain inconsistencies and defects as well as common features of multiphase and thermal LB models. Recent developments in improving the thermodynamic and hydrodynamic consistency, reducing spurious currents, enhancing the numerical stability, etc., are highlighted. These efforts have put the LB method on a firmer theoretical foundation with enhanced LB models that can achieve larger liquid-gas density ratio, higher Reynolds number and flexible surface tension. Examples of applications are provided in fuel cells and batteries, droplet collision, boiling heat transfer and evaporation, and energy storage. Finally, further developments and future prospect of the LB method are outlined for thermofluids and energy applications.3

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Section: Fig 21 Simulation Of the Collision Between Two Droplets Anmentioning

confidence: 99%

Lattice Boltzmann methods for multiphase flow and phase-change heat transfer

Luo

Kang

et al. 2016

Progress in Energy and Combustion Science

777

373

View full text Add to dashboard Cite

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“…More details with respect to the nondimensionalization can be found in [59]. Special care is taken when handling the external-force term in the momentum equation (7), which involves the nondimensional gravitational acceleration in the form of (15) Given that t * and l * are both negligibly small, instead of the terrestrial value of 9.8 m/s 2 , we rely on an artificial gravity, which incidentally needs to be inflated multiple orders of magnitude [48,62], to impose any meaningful impacts on bubble growth and, for that matter, contact-line propagation. (Actually, the effect of the consequently different bubble growth rates on contact-line motion will constitute the main focus of…”

Section: B Nondimensionalizationmentioning

confidence: 99%

Contact-line behavior in boiling on a heterogeneous surface: Physical insights from diffuse-interface modeling

et al. 2020

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Enhancement of boiling heat transfer on biphilic (mixed-wettability) surfaces faces a sudden reversal at low pressures, which is brought about by excessive contactline spreading across the wetting heterogeneities. We employ the diffuse-interface approach to numerically study bubble expansion on a heating surface that consists of opposing wettabilities. The results show a dramatic shift in the dynamics of traversing contact line across the wettability divide under different gravities, which correspond to variable bubble growth rates. Specifically, it is found that the contact-line propagation tends to follow closely the rapidly expanding bubble at low gravity, with only a brief interruption at the border between the hydrophobic and hydrophilic sections of the surface. Only when the bubble growth becomes sufficiently weakened at high gravity does the contact line get slowed down drastically to the point of being

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“…Boiling is a central phenomenon in technological and industrial applications as diverse as thermal management in electronics, power generation and chemical processing 1 – 3 . In such applications, it is of immense importance to enhance the energy efficiency by increasing the critical heat flux (CHF), the highest heat flux a boiling substrate can achieve, as well as reducing operational risks caused by the notorious “boiling crisis”, a catastrophic failure in boilers or heat exchanging devices 4 .…”

Section: Introductionmentioning

confidence: 99%

Critical heat flux enhancement in pool boiling through increased rewetting on nanopillar array surfaces

Nguyen

Liu

Kayes

et al. 2018

Sci Rep

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Boiling is a key heat transfer process for a variety of power generation and thermal management technologies. We show that nanopillar arrays fabricated on a substrate enhance both the critical heat flux (CHF) and the critical temperature at CHF of the substrate and thus, effectively increase the limit of boiling before the boiling crisis is triggered. We reveal that the enhancement in both the CHF and the critical temperature results from an intensified rewetting process which increases with the height of nanopillars. We develop a predictive model based on experimental measurements of rewetting velocity to predict the enhancement in CHF and critical temperature of the nanopillar substrates. This model is critical for understanding how to control boiling enhancement and designing various nanostructured surfaces into specific applications.

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Single-bubble dynamics in pool boiling of one-component fluids

Cited by 22 publications

References 54 publications

Lattice Boltzmann methods for multiphase flow and phase-change heat transfer

Lattice Boltzmann methods for multiphase flow and phase-change heat transfer

Contact-line behavior in boiling on a heterogeneous surface: Physical insights from diffuse-interface modeling

Critical heat flux enhancement in pool boiling through increased rewetting on nanopillar array surfaces

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