Analysis of metabolic CO2 concentration field in a small mechanically ventilated occupied enclosure

“…On the contrary, the simulation by Wang et al 54 that focused on the CO 2 concentration in a personalized work environment (PWE) showed that the inhaled CO 2 concentration was higher than the volume‐averaged concentration over time, which could be caused by upward flow towards the ceiling. Angelova et al 38–40 also indicated that a region of high CO 2 concentration (1200 ppm and above) was formed in front of the occupant's head when there was downward flow from the ceiling, and they assumed that the inhaled CO 2 concentration differed from the CO 2 concentration measured at both the inlet and outlet of the chamber. Thus, the flow field in the breathing zone and the locations of the outdoor supply inlet and exhaust outlet strongly affect the inhaled CO 2 concentration.…”

“…showed that the inhaled CO 2 concentration was higher than the volume-averaged concentration over time, which could be caused by upward flow towards the ceiling. Angelova et al [38][39][40]…”

“…Prediction of human CO 2 emissions during continuous breathing with inhalation and exhalation modes requires reliable modeling of human interaction with the ambient indoor environment. For this purpose, CSPs incorporating a computational fluid dynamics (CFD) approach were developed because they make it possible to simulate the non‐uniform airflow pattern and temperature distribution surrounding the human body indoors, together with CO 2 emissions from breathing 32–40 . Bulińska and Buliński 35 analyzed three different breathing models that simulate a micro‐environment around the human body, particularly the CO 2 concentration distribution emitted by a sleeping person.…”

“…For this purpose, CSPs incorporating a computational fluid dynamics (CFD) approach were developed because they make it possible to simulate the non-uniform airflow pattern and temperature distribution surrounding the human body indoors, together with CO 2 emissions from breathing. [32][33][34][35][36][37][38][39][40] Bulińska and Buliński 35 analyzed three different breathing models that simulate a micro-environment around the human body, particularly the CO 2 concentration distribution emitted by a sleeping person. They confirmed that complete breathing with inhalation and exhalation should be included in an accurate prediction of contaminant transport from humans.…”

Prediction of exhaled carbon dioxide concentration using a computer‐simulated person that included alveolar gas exchange

“…On the contrary, the simulation by Wang et al 54 that focused on the CO 2 concentration in a personalized work environment (PWE) showed that the inhaled CO 2 concentration was higher than the volume‐averaged concentration over time, which could be caused by upward flow towards the ceiling. Angelova et al 38–40 also indicated that a region of high CO 2 concentration (1200 ppm and above) was formed in front of the occupant's head when there was downward flow from the ceiling, and they assumed that the inhaled CO 2 concentration differed from the CO 2 concentration measured at both the inlet and outlet of the chamber. Thus, the flow field in the breathing zone and the locations of the outdoor supply inlet and exhaust outlet strongly affect the inhaled CO 2 concentration.…”

“…showed that the inhaled CO 2 concentration was higher than the volume-averaged concentration over time, which could be caused by upward flow towards the ceiling. Angelova et al [38][39][40]…”

“…Prediction of human CO 2 emissions during continuous breathing with inhalation and exhalation modes requires reliable modeling of human interaction with the ambient indoor environment. For this purpose, CSPs incorporating a computational fluid dynamics (CFD) approach were developed because they make it possible to simulate the non‐uniform airflow pattern and temperature distribution surrounding the human body indoors, together with CO 2 emissions from breathing 32–40 . Bulińska and Buliński 35 analyzed three different breathing models that simulate a micro‐environment around the human body, particularly the CO 2 concentration distribution emitted by a sleeping person.…”

“…For this purpose, CSPs incorporating a computational fluid dynamics (CFD) approach were developed because they make it possible to simulate the non-uniform airflow pattern and temperature distribution surrounding the human body indoors, together with CO 2 emissions from breathing. [32][33][34][35][36][37][38][39][40] Bulińska and Buliński 35 analyzed three different breathing models that simulate a micro-environment around the human body, particularly the CO 2 concentration distribution emitted by a sleeping person. They confirmed that complete breathing with inhalation and exhalation should be included in an accurate prediction of contaminant transport from humans.…”

Prediction of exhaled carbon dioxide concentration using a computer‐simulated person that included alveolar gas exchange

Thermal Manikins – General Features and Applications

Supercomputer Modelling of Human Respiration Using Virtual Thermal Manikin Under Test Conditions