An increasing number of consumers are scanning egg cartons for the words “cage-free,” “natural,” or “free-range.”
So much so, in fact, that many large institutional buyers of eggs and egg products have announced that within 10 years they will do business only with cage-free production facilities, according to a U.S. Department of Agriculture report.
That shift in consumer behavior is prompting some poultry producers to change the manner in which chickens are housed and cared for, and research underway in Penn State’s College of Agricultural Sciences will help them convert from traditional caged housing to noncaged systems that continue to safeguard the health and safety of flocks and employees.
“Many consumers want food-producing animals such as chickens to live in environments that are nonconfining,” said Eileen Fabian, professor of agricultural engineering and environmental biophysics.
“Poultry facilities are going through the largest evolution in design due to this demand. But the overall sustainability of cage-free systems is in question when one considers the increased feed, fuel, land and labor they require.”
Building on prior accomplishments in agricultural structure and ventilation design, Fabian and colleagues Long Chen, doctoral student; Paul Patterson, professor of poultry science; Daniel Hofstetter, extension research assistant; and John Cimbala, professor of mechanical engineering in the College of Engineering, are examining various cage-free building configurations.
Effective systems
The purpose of their research is to design systems for improving indoor air quality and uniformity in cage-free houses, especially those that provide supplemental heat, and to develop mechanisms that reduce airborne disease spread within and between hen houses.
“Many commercial facilities have multiple buildings that each house between 20,000 and 50,000 hens, so there’s a lot to consider when creating a cage-free housing design,” Fabian said.
Blueprints will be created using a computer design and analysis tool called computational fluid dynamics. This allows researchers to enter a design model and then run simulations that investigate how changes to ventilation-system configuration will affect indoor air flow patterns and air-quality parameters such as temperature, ammonia and dust concentrations, and potential disease particle spread during an outbreak.
Click here to see more...