![]() ![]() During incubation, you want the moisture to evaporate at the right rate in order for the embryo to develop and hatch properly. The longer they are stored, the more moisture evaporates through the pores in the eggshell. When air is dry, it has low humidity and will absorb moisture from the surroundings through evaporation. Humidity is the amount of moisture that is in the air. Consider investing in a heat recovery system.This post may contain affiliate links.Perform a cost-benefit analysis within these specifications, to establish the most advantageous combination of temperature, relative humidity and energy usage to achieve the highest hatchability and optimum chick quality.Pre-condition hot, humid outside air to the inlet specifications recommended by your incubator supplier, to reduce its moisture content.Aim for a linear rather than non-linear weight loss profile, to prevent insufficient weight loss that will inevitably arise from failing to achieve the low %RH set points required during the last days of incubation using a NLWL-profile.Additional, albeit reduced, energy costs will still increase the cost price of the day-old-chick – but this does give the hatchery manager an additional tool for better controlling hatchability and chick quality in a challenging, hot and humid climate. A heat recovery system, which uses energy present in the return water from the incubator’s cooling circuit, is an effective way to reduce heating costs. It requires energy, both for the cooling needed for dehumidification and also to subsequently re-heat the air to a recommended inlet temperature of 25☌ (+/- 2 ☌). There is a downside to treating hot, humid outside air in this way. Again using the above example, each kilogram of air entering the incubator now has the capacity to extract 21 – 12 = 9 gram of water. Outside air of 30☌ / 75%RH can be climatized to, for example, 25☌ / 60%RH, which significantly reduces the water content of the air from 20g H2O/kg to approx. ![]() It is possible, at least partially, to overcome these challenges and minimize the need for high ventilation rates early in incubation, by optimizing the temperature and relative humidity of inlet air using an Air Handling Unit. In this scenario, a linear weight loss profile based on a constant RH% of approx. This is because when RH% set point inside the setter is, for example, 45%RH, the inlet air (30☌ / 75%RH=20g H2O/kg) already contains more water (37.5 ☌/45 %RH = approx. Such low levels of RH% simply cannot be achieved, even when air valves are 100% open. less than 45%) during the second half of incubation, is not feasible in hot, humid conditions. This requires a lot of ventilation, starting early in incubation, to allow the hatching eggs to lose sufficient weight.Īdopting a non-linear weight loss profile that starts incubation with high RH% (by sealing the setter for several days), then compensating for low weight loss by applying a low RH% (ie. However, using the example above, each kilogram of air entering the incubator can extract only 21g – 20g = 1 gram of water. This limits evaporation from the eggs, making it impossible to achieve 12% weight loss.īy ventilating the incubator with fresh air, evaporating water from the eggs can be removed via the outlet, while maintaining an optimal incubation climate. With the setter’s air valves closed, evaporating water from the eggs will increase both the absolute (gH2O/kg air) and relative (RH%) humidity of air in the setter. If we assume a setter climate of 37.5☌ and, with the aim of optimising weight loss from fresh egg weight at transfer of 12%, we choose a set point of 50% RH, the air in the setter will contain approx. For example, a moderately hot and humid climate of 30☌ with 75%RH at sea level contains approx.
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