Publication detail

Validated numerical simulation of airflow in child respiratory airways

BĚLKA, M. MALÝ, M. CEJPEK, O. ELCNER, J. LÍZAL, F. JEDELSKÝ, J. JÍCHA, M.

English title

Validated numerical simulation of airflow in child respiratory airways

Type

article in a collection out of WoS and Scopus

Language

en

Original abstract

Both pulmonary airway geometry and breathing pattern evolve from birth to adulthood. These gradual changes significantly influence airflow dynamics and subsequently particle transport and deposition. Regarding the airway structure, the differences between infants and adults are most profound till 5 years of age. Since that age the child airway geometry can be downsized from adult lungs. The objective of the present work was to investigate airflow patterns in child airways. The digital model of male respiratory airways was downsized to dimensionally correspond to a 5–year old child. Airflow simulations with properly validated RANS k–ω turbulence model were performed under steady inhalation boundary conditions. The inspiratory flow rate was 12.5 L/min. The velocity profiles just upstream of the first bifurcation were validated by LDA experiments. A replica of the same geometry as the one used in the simulation was 3D printed and part of the trachea was replaced by a glass tube. Laser–Doppler anemometry measurements in several points upstream of the first bifurcation were carried out. The validated flow patterns were compared to the ones obtained in adult lungs.

English abstract

Both pulmonary airway geometry and breathing pattern evolve from birth to adulthood. These gradual changes significantly influence airflow dynamics and subsequently particle transport and deposition. Regarding the airway structure, the differences between infants and adults are most profound till 5 years of age. Since that age the child airway geometry can be downsized from adult lungs. The objective of the present work was to investigate airflow patterns in child airways. The digital model of male respiratory airways was downsized to dimensionally correspond to a 5–year old child. Airflow simulations with properly validated RANS k–ω turbulence model were performed under steady inhalation boundary conditions. The inspiratory flow rate was 12.5 L/min. The velocity profiles just upstream of the first bifurcation were validated by LDA experiments. A replica of the same geometry as the one used in the simulation was 3D printed and part of the trachea was replaced by a glass tube. Laser–Doppler anemometry measurements in several points upstream of the first bifurcation were carried out. The validated flow patterns were compared to the ones obtained in adult lungs.

Keywords in English

respiratory airways, numerical simulation, child, aerosol

Released

23.11.2021

Publisher

Technical University of Liberec

Location

Liberec

Pages from–to

1–5

Pages count

5

BIBTEX


@inproceedings{BUT176041,
  author="Miloslav {Bělka} and Milan {Malý} and Ondřej {Cejpek} and Jakub {Elcner} and František {Lízal} and Jan {Jedelský} and Miroslav {Jícha},
  title="Validated numerical simulation of airflow in child respiratory airways",
  year="2021",
  month="November",
  pages="1--5",
  publisher="Technical University of Liberec",
  address="Liberec"
}