When livestock facilities in Korea have been changed larger and denser, rearing conditions have been getting worse and the productivity of animal production have been decreased. Especially in the cold season, the minimized ventilation has generally been operated to save energy cost in Korea resultin...
When livestock facilities in Korea have been changed larger and denser, rearing conditions have been getting worse and the productivity of animal production have been decreased. Especially in the cold season, the minimized ventilation has generally been operated to save energy cost in Korea resulting in very poor environmental condition and high mortality. While the stability, suitability, and uniformity of the rearing condition are the most important for high productivity, the ventilation configuration is the most important to improve the rearing condition seasonally. But, it is so difficult to analyze the internal air flow and the environmental factors by conducting only field experiment because the weather condition is very unpredictable and unstable as well as the structural specification can not be easily changed by the researchers considering cost and labor. Accordingly, an aerodynamic computer simulation was adopted to this study to overcome the weakness of conducting field experiment and study the aerodynamic itself. It has been supposed that the airflow is the main mechanism of heat, mass, and momentum transfers. To make the simulation model accurately and actually, simplified pig models were also developed. The accuracy of the CFD simulation model was enhanced by 4.4 % of errors compared with the data collected from field experiments. In this paper, using the verified CFD model, the CFD computed internal rearing condition of the mechanically ventilated pig house were analyzed quantitatively as well as qualitatively. Later, this developed model will be computed time-dependently to effectively analyze the seasonal ventilation efficiency more practically and extensively with tracer gas decay theory.
When livestock facilities in Korea have been changed larger and denser, rearing conditions have been getting worse and the productivity of animal production have been decreased. Especially in the cold season, the minimized ventilation has generally been operated to save energy cost in Korea resulting in very poor environmental condition and high mortality. While the stability, suitability, and uniformity of the rearing condition are the most important for high productivity, the ventilation configuration is the most important to improve the rearing condition seasonally. But, it is so difficult to analyze the internal air flow and the environmental factors by conducting only field experiment because the weather condition is very unpredictable and unstable as well as the structural specification can not be easily changed by the researchers considering cost and labor. Accordingly, an aerodynamic computer simulation was adopted to this study to overcome the weakness of conducting field experiment and study the aerodynamic itself. It has been supposed that the airflow is the main mechanism of heat, mass, and momentum transfers. To make the simulation model accurately and actually, simplified pig models were also developed. The accuracy of the CFD simulation model was enhanced by 4.4 % of errors compared with the data collected from field experiments. In this paper, using the verified CFD model, the CFD computed internal rearing condition of the mechanically ventilated pig house were analyzed quantitatively as well as qualitatively. Later, this developed model will be computed time-dependently to effectively analyze the seasonal ventilation efficiency more practically and extensively with tracer gas decay theory.
Bjerg, B., K. Svidt, & G. Zhang. 2002. Modeling of air inlets in CFD prediction of airflow in ventilated animal houses. Computers and Electronics in Agriculture 34. pp. 223-235
Fluent manual, 2006, Version 6.2.2. Lebanon, N.H. Fluent Inc.
Harral, B. B., & C. R. Boon. 1997. Comparison of predicted and measured air flow patterns in a mechanically ventilated livestock building without animals. J. Agric. Eng. Res. 66. pp. 221-228
Lee, I., W. Park, & B. Yu. 2002. Optimum design of forced ventilation system of piglet house using computer simulation. Presented at the 2002 ASAE annual international meeting. ASAE paper number : 024109. St, Joseph. Mich. :ASAE
Lee, I. 2007. Evaluation of CFD accuracy for the study on ventilation of a naturally ventilated broiler house. JARQ
NAQS, National agricultural products quality management service, 국립농산물품질관리원, http://www.naqs.go.kr
Norton, T., D. Sun, J. Grant, R. Fallon, & V. Dodd. 2007. Applications of computational fluid dynamics(CFD) in the modelling and design of ventilation systems in a agricultural industry : A review. Bioresource Technology
Statistical Survey of Livestock Industry(SSLI). 2006. NAPQMS(National Agricultural Product Quality Management Service), Korea
Sun, H., R. Stowell, H. Keener, D. Elwell, & F. Michel. 2002. Two-dimensional computational fluid dynamics modelling of air velocity and ammonia distribution in a high rise hog building. Transactions of the ASAE 45, pp. 1559-1568
Sun, H., H. Keener, W. Deng, & F. Michel. 2004. Development and validation of 3-D CFD models to simulate airflow and ammonia distribution in a high-rise hog building during summer and winter conditions. Agricultural Engineering International : the CIGR Journal of Scientific Research and Development. Manuscript BC 04 004. Vol. VI
Wathes, C. M. & D. R. Charles. 1994. Livestock Housing. Cab International. UK
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