An egg flat identification system for identifying an egg flat among a collection of egg flats is provided. Such a system includes a first measurement device configured to determine a first measurement of a plurality of eggs carried by an egg flat. A processor is in communication with the first measurement device. The processor is configured to receive the first measurements from the first measurement device. A second measurement device is configured to determine a second measurement of the eggs in the collection of egg flats. The second measurement device is in communication with the processor such that the processor is capable of receiving the second measurements. The processor compares the second measurements with the first measurements so as to identify a respective egg flat among the collection of egg flats.

An apparatus to identify upside-down eggs of a batch of eggs includes a heating module configured to expose an air cell in each egg of the batch of eggs to a radiation flux. The apparatus also includes an imaging module with a thermal camera configured to capture thermal images of the batch of eggs when the eggs are not exposed to the radiation flux. The apparatus further includes an analyzer module configured to detect the presence of a heated zone in the air cell of each egg from the thermal images and identify upside-down eggs based on the presence of the heated zone. A method to identify upside-down eggs from a batch of eggs includes heating the batch of eggs with a radiation source, such as an infrared source, so as to generate a hot zone inside an air cell of each egg without significantly heating the rest of the eggs. Thermal images of the eggs are captured while the eggs are not exposed to the radiation source, analyzed to detect the presence of the hot zone and to identify the upside down eggs.

An apparatus to identify upside-down eggs of a batch of eggs includes a heating module configured to expose an air cell in each egg of the batch of eggs to a radiation flux. The apparatus also includes an imaging module with a thermal camera configured to capture thermal images of the batch of eggs when the eggs are not exposed to the radiation flux. The apparatus further includes an analyzer module configured to detect the presence of a heated zone in the air cell of each egg from the thermal images and identify upside-down eggs based on the presence of the heated zone. A method to identify upside-down eggs from a batch of eggs includes heating the batch of eggs with a radiation source, such as an infrared source, so as to generate a hot zone inside an air cell of each egg without significantly heating the rest of the eggs. Thermal images of the eggs are captured while the eggs are not exposed to the radiation source, analyzed to detect the presence of the hot zone and to identify the upside down eggs.

Methods and apparatus for processing eggs based upon a characteristic such as gender are provided. Material is extracted from each of a plurality of live eggs, the extracted material is assayed to identify eggs having the characteristic, and then eggs identified as having the characteristic are processed accordingly.

An egg grasp device is provided. Such a device includes a body and a plurality of elongated members extending from the body. The elongated members are interlaced to form a sheath capable of retaining an egg. The sheath has a distal end and a proximal end at which the elongated members are operably engaged with the body. The elongated members cooperate to define an opening at the distal end through which an egg is received when the elongated members engage and deflect about an egg such that the egg is seated within the sheath. Associated systems and methods are also provided.

The present invention discloses a method and a device for non-destructive sorting of fertilization information of hatching eggs before incubation. The method comprises the following steps: obtaining a first time sequence feature of hatching eggs and collecting spectrum data of the hatching eggs according to the first time sequence feature; preprocessing the spectrum data; selecting the preprocessed spectrum data to obtain a feature band; constructing a hatching egg classification neural network model and training the hatching egg classification neural network model; classifying the hatching egg information according to the feature band by using the trained hatching egg classification neural network model to obtain fertilization information; and obtaining a second time sequence feature of the hatching eggs, and sorting the hatching eggs. The present invention improves the precision of detecting the fertilization information of hatching eggs.

The present disclosure relates to a device for delivering substances to specific embryonic structures, including heart and blood vessels, within a developing avian egg. The disclosure also relates to methods of using the device to produce enhanced avian embryos. Methods include administering to chicken embryos various substances, including vaccines, nutrients, and stem cells. Chickens resulting from enhanced avian embryos have advantages, including greater growth potential and resistance to pathogen infection/infestation.

The present disclosure relates to a device for delivering substances to specific embryonic structures, including heart and blood vessels, within a developing avian egg. The disclosure also relates to methods of using the device to produce enhanced avian embryos. Methods include administering to chicken embryos various substances, including vaccines, nutrients, and stem cells. Chickens resulting from enhanced avian embryos have advantages, including greater growth potential and resistance to pathogen infection/infestation.

The present invention relates to a method and device for automatically inspecting one or more eggs contactlessly. According to the invention, the following steps are carried out: a) a millimeter-wave radio-frequency signal is transmitted by a transmitter towards an egg, b) a millimeter-wave radio-frequency signal reflected by said egg is detected by means of a sensor (14), said sensor (14) being placed at distance from said egg, c) the intensity of the reflected millimeter-wave radio-frequency signal is analyzed as a function of the distance traveled by the reflected signal and the radar echo thus obtained is compared with one or more reference radar echoes each representative of one egg state, so as to deduce the egg's current state therefrom.

An egg flat identification system for identifying an egg flat among a collection of egg flats is provided. Such a system includes a first measurement device configured to determine a first measurement of a plurality of eggs carried by an egg flat. A processor is in communication with the first measurement device. The processor is configured to receive the first measurements from the first measurement device. A second measurement device is configured to determine a second measurement of the eggs in the collection of egg flats. The second measurement device is in communication with the processor such that the processor is capable of receiving the second measurements. The processor compares the second measurements with the first measurements so as to identify a respective egg flat among the collection of egg flats.