Diagnosis and validation by computational fluid dynamics of poultry house with negative pressure ventilation

Cunha, Gisele C. de A.; Lopes, José; Furtado, Dermeval A.; Borges, Valéria Peixoto; Freire, Elias A.; Nascimento, José Wallace Barbosa do

doi:10.1590/1807-1929/agriambi.v23n10p761-767

Cited by 3 publications

(1 citation statement)

References 10 publications

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“…The distribution of environmental variables and thermal comfort provided a more comprehensive understanding of ventilation and thermal conditions in the poultry house and provided insights to improve facility design and management to enhance poultry welfare [74][75][76]. In a specific study focused on thermal comfort issues, Tong et al [55] employed a 3D CFD model to assess the temperature-humidity index (THI) and heat stress levels during summer, autumn, and winter.…”

Section: Air Temperature-humidity Distributionmentioning

confidence: 99%

Modeling Environmental Conditions in Poultry Production: Computational Fluid Dynamics Approach

Küçüktopçu,

Cemek,

Simsek

2024

Animals

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In recent years, computational fluid dynamics (CFD) has become increasingly important and has proven to be an effective method for assessing environmental conditions in poultry houses. CFD offers simplicity, efficiency, and rapidity in assessing and optimizing poultry house environments, thereby fueling greater interest in its application. This article aims to facilitate researchers in their search for relevant CFD studies in poultry housing environmental conditions by providing an in-depth review of the latest advancements in this field. It has been found that CFD has been widely employed to study and analyze various aspects of poultry house ventilation and air quality under the following five main headings: inlet and fan configuration, ventilation system design, air temperature–humidity distribution, airflow distribution, and particle matter and gas emission. The most commonly used turbulence models in poultry buildings are the standard k-ε, renormalization group (RNG) k-ε, and realizable k-ε models. Additionally, this article presents key solutions with a summary and visualization of fundamental approaches employed in addressing path planning problems within the CFD process. Furthermore, potential challenges, such as data acquisition, validation, computational resource requirements, meshing, and the selection of a proper turbulence model, are discussed, and avenues for future research (the integration of machine learning, building information modeling, and feedback control systems with CFD) are explored.

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Section: Air Temperature-humidity Distributionmentioning

confidence: 99%

Modeling Environmental Conditions in Poultry Production: Computational Fluid Dynamics Approach

Küçüktopçu,

Cemek,

Simsek

2024

Animals

View full text Add to dashboard Cite

show abstract

Towards modelling, and analysis of differential pressure and air velocity in a mechanical ventilation poultry house: Application for hot climates

Elghardouf

Lahlouh

Elakkary

et al. 2023

Heliyon

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Evaluation of heat stress using temperature-humidity index in laying hens in battery cages under Bursa conditions

Kılıç,

Yaylı

2024

Harran Tarım Ve Gıda Bilimleri Dergisi

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Heat stress has become a more severe threat to the poultry industry with increasing global warming. Poultry is a sensitive animal affected more quickly by environmental conditions than other farm animals. Therefore, they are more easily exposed to heat stress. High temperature and relative humidity are significant environmental factors affecting animal growth, productivity, and welfare by causing heat stress. In laying hens under heat stress, egg production decreases, feed consumption increases, feed efficiency decreases, and deterioration in egg quality occurs. This study aims to determine the heat stress of laying hens using the temperature-humidity index (THI) in a farm where commercial egg production is conducted in battery cages in the Bursa region. According to the study results, the highest THI values occurred in the summer months and were at a critical level for chickens in July (26.0) and August (24.8). There is no statistically significant relationship between egg yields obtained in spring, summer, and autumn and the calculated temperature humidity index values. There is an inverse relationship between indoor temperature and egg production.

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Diagnosis and validation by computational fluid dynamics of poultry house with negative pressure ventilation

Cited by 3 publications

References 10 publications

Modeling Environmental Conditions in Poultry Production: Computational Fluid Dynamics Approach

Modeling Environmental Conditions in Poultry Production: Computational Fluid Dynamics Approach

Towards modelling, and analysis of differential pressure and air velocity in a mechanical ventilation poultry house: Application for hot climates

Evaluation of heat stress using temperature-humidity index in laying hens in battery cages under Bursa conditions

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