Numerical predictions of air temperature and velocity distribution to assist in the design of natural ventilation piggery buildings
Article
| Article Title | Numerical predictions of air temperature and velocity distribution to assist in the design of natural ventilation piggery buildings |
|---|---|
| ERA Journal ID | 3449 |
| Article Category | Article |
| Authors | |
| Author | Mossad, R. R. |
| Editors | Chen, Guangnan |
| Journal Title | Australian Journal of Multi-Disciplinary Engineering |
| Journal Citation | 8 (2), pp. 181-187 |
| Number of Pages | 7 |
| Year | 2011 |
| Publisher | Taylor & Francis |
| Place of Publication | Sydney, Australia |
| ISSN | 0812-3314 |
| 1441-6611 | |
| 1448-8388 | |
| Abstract | Pigs are subjected to intensive environment control and management for higher productivity due to their sensitivity to climatic variation, which affects their growth and impacts greatly on the profitability of this industry. The appropriate temperature and air speed inside a piggery that meets the thermal comfort of the pigs depends on the age of the pigs; in this study grower pigs (32-52 kg) are considered. The aim of the current work is to model the air flow in a natural ventilation piggery numerically and hence predict the velocity and temperature of the air inside the piggery. The effect of some variation in the design of the piggery on the environment inside the piggery, and more specifically at the pigs’ level, has been also investigated. A steady two-dimensional numerical model including the effect of buoyancy, turbulence and heat generated by the pigs was solved using the computational fluid dynamics software Fluent, which is based on the integral volume method. Temperature and air speed inside the piggery and at the pigs’ level were predicted for a particular wind velocity and temperature to facilitate the comparison of the effect of the different variations in the design proposed in this study. These variations were reducing the height of the outer wall of the piggery to the same level as the pens and changing the type of fence used in the pens as well as adding louvers in the air opening, changing the shape of the roof and adding insulation to the roof. Air was assumed to enter the piggery at speed of 0.92 m/s to the southwest and at temperature of 34 °C. The results suggest that varying the type of fence from a solid internal fence to ones made of separated bars (new fence) only did not have much impact on the environment inside the piggery. When this change was combined with the other variation such as lowering the outer walls it made some improvements. Combining the new fence, lowering the outer walls and changing the shape of the roof resulted in the highest increase in the air speed of about 0.2-0.4 m/s at the pigs’ level in comparison to the original design. Unfortunately this reduction was not large enough to bring temperature and air speed to the thermal comfort of these |
| Keywords | upper air temperature; animal dwellings; livestock housing; piggery; computational fluid dynamics; turbulence |
| ANZSRC Field of Research 2020 | 401204. Computational methods in fluid flow, heat and mass transfer (incl. computational fluid dynamics) |
| 300306. Animal welfare | |
| 401706. Numerical modelling and mechanical characterisation | |
| Public Notes | Files associated with this item cannot be displayed due to copyright restrictions. |
| Byline Affiliations | Australian Centre for Sustainable Catchments |
| Institution of Origin | University of Southern Queensland |
https://research.usq.edu.au/item/q0zzq/numerical-predictions-of-air-temperature-and-velocity-distribution-to-assist-in-the-design-of-natural-ventilation-piggery-buildings
2018
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