Three-Dimensional Numerical Simulation of Particle Focusing and Separation in Viscoelastic Fluids

Ni, Chao; Jiang, Di

doi:10.3390/mi11100908

Cited by 13 publications

(8 citation statements)

References 40 publications

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“…2019), channel flows (Coclite et al. 2020), stratified flows (Jyothi, Renganathan & Pushpavanam 2019) and viscoelastic flows (Ni & Jiang 2020). Hur et al.…”

Section: Introductionmentioning

confidence: 99%

Numerical investigation of the formation and stability of homogeneous pairs of soft particles in inertial microfluidics

Owen

2022

J. Fluid Mech.

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We investigate the formation and stability of a pair of identical soft capsules in channel flow under mild inertia. We employ a combination of the lattice Boltzmann, finite element and immersed boundary methods to simulate the elastic particles in flow. Validation tests show excellent agreement with numerical results obtained by other research groups. Our results reveal new trajectory types that have not been observed for pairs of rigid particles. While particle softness increases the likelihood of a stable pair forming, the pair stability is determined by the lateral position of the particles. A key finding is that stabilisation of the axial distance occurs after lateral migration of the particles. During the later phase of pair formation, particles undergo damped oscillations that are independent of initial conditions. These damped oscillations are driven by a strong hydrodynamic coupling of the particle dynamics, particle inertia and viscous dissipation. While the frequency and damping coefficient of the oscillations depend on particle softness, the pair formation time is largely determined by the initial particle positions: the time to form a stable pair grows exponentially with the initial axial distance. Our results demonstrate that particle softness has a strong impact on the behaviour of particle pairs. The findings could have significant ramifications for microfluidic applications where a constant and reliable axial distance between particles is required, such as flow cytometry.

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“…2019), channel flows (Coclite et al. 2020), stratified flows (Jyothi, Renganathan & Pushpavanam 2019) and viscoelastic flows (Ni & Jiang 2020). Hur et al.…”

Section: Introductionmentioning

confidence: 99%

Numerical investigation of the formation and stability of homogeneous pairs of soft particles in inertial microfluidics

Owen

2022

J. Fluid Mech.

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“…Nanofluids can be considered as uniformly mixed and continuously flowing fluids based on the assumption. The physical properties of the nanofluid are determined by the properties of the base liquid and the nanoparticle 29,30 . Table 8 shows the physical property parameters of three metal nanoparticles and deionized water 31 at 25°C.…”

Section: Resultsmentioning

confidence: 99%

“…The physical properties of the nanofluid are determined by the properties of the base liquid and the nanoparticle. 29,30 Table 8 shows the physical property parameters of three metal nanoparticles and deionized water 31 at 25°C. The volume fractions of different water-based nanofluids namely Cu-water, Al-water and Ag-water were set to 2%.…”

Section: Nanofluidsmentioning

confidence: 99%

Numerical investigation on thermal performance of battery module with LCP‐AFC cooling system applied in electric vehicle

Guo

Zhu

et al. 2022

Energy Science & Engineering

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To improve the thermal performance of electric vehicle batteries, a novel cooling system of liquid cold plates coupled with air flow channels (LCP-AFC) for battery thermal management was proposed. Three-dimensional models were established for simulation. The effects of five factors on the heat dissipation of the electric vehicle battery module were studied, which included the battery discharge rate, inlet temperature of cooling liquid, nanofluids, airflow velocity, liquid, and air flow directions. The results showed that the maximum temperature T max and temperature difference ΔT of the battery module under 1 C discharge rate could be reduced by 1.1°C and 0.92°C compared to the single liquid cooling. Comparing the LCP-AFC with single air cooling, the T max and ΔT of the battery module under 4 C discharge rate could be reduced by 18.74°C and 2.71°C. The temperature uniformity of the battery module was not satisfied with the inlet temperature of the cooling liquid, which was lower than 15°C. The heat transfer performance was improved by adding Al, Cu, or Ag nanoparticles into the deionized water. Among them, Ag-water nanofluid had the most significant cooling effect. Parallel flow indicated better thermal performance than cross flow and counter flow. The developed cooling system of LCP-AFC offers a new method to design lithiumion battery thermal management system for controlling temperature distribution of a battery module.

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“…Another method of manipulating the equilibrium position of particles is through the use of viscoelastic liquids. Ni and Jiang [149] demonstrated that the equilibrium position can be controlled through the elasticity number, the ratio between inertial and elastic forces, with increasing elastic number resulting in positions closer to the channel wall.…”

Section: Fundamental Migration Dynamics Prohm and Starkmentioning

confidence: 99%

Lattice-Boltzmann Modelling for Inertial Particle Microfluidics Applications — A Tutorial Review

Owen

Kechagidis

Bazaz

et al. 2023

Preprint

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Inertial particle microfluidics (IPMF) is an emerging technology for the manipulation and separation of microparticles and biological cells. Since the flow physics of IPMF is complex and experimental studies are often time-consuming or costly, computer simulations can offer complementary insights. In this tutorial review, we provide a guide for researchers who are exploring the potential of the lattice-Boltzmann (LB) method for simulating IPMF applications. We first review the existing literature to establish the state of the art of LB-based IPMF modelling. After summarising the physics of IPMF, we then present related methods used in LB models for IPMF and show several case studies of LB simulations for a range of IPMF scenarios. Finally, we conclude with an outlook and several proposed research directions.

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Three-Dimensional Numerical Simulation of Particle Focusing and Separation in Viscoelastic Fluids

Cited by 13 publications

References 40 publications

Numerical investigation of the formation and stability of homogeneous pairs of soft particles in inertial microfluidics

Numerical investigation of the formation and stability of homogeneous pairs of soft particles in inertial microfluidics

Numerical investigation on thermal performance of battery module with LCP‐AFC cooling system applied in electric vehicle

Lattice-Boltzmann Modelling for Inertial Particle Microfluidics Applications — A Tutorial Review

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