An egg-examining device, comprising a sampling device, by which a liquid sample to be taken can be taken from an egg of a rack loaded with eggs, a feeding device for feeding the rack loaded with eggs to the sampling device, and a control unit, by which the feeding device and the sampling device can be controlled. The feeding device feeds the rack to the sampling device at an oblique angle of between 20° and 80° to a plane perpendicular to the direction of gravity. A lifting-out device is provided, by which the egg can be lifted out of the rack and by which the egg can be put into a sampling position, in which the liquid amount to be taken can be taken from the egg by the sampling device.

An egg-examining device, comprising a sampling device, by which a liquid sample to be taken can be taken from an egg of a rack loaded with eggs, a feeding device for feeding the rack loaded with eggs to the sampling device, and a control unit, by which the feeding device and the sampling device can be controlled. The feeding device feeds the rack to the sampling device at an oblique angle of between 20° and 80° to a plane perpendicular to the direction of gravity. A lifting-out device is provided, by which the egg can be lifted out of the rack and by which the egg can be put into a sampling position, in which the liquid amount to be taken can be taken from the egg by the sampling device.

The present invention relates to a computer-controlled system for non-invasively identifying the location of the air cell of an egg and determining a preferred extraction point relative to the position of the air cell of the egg, the system comprising: a. an egg manipulator to hold and orient one or more eggs in a defined position; b. a candling unit comprising one or more light sources and one or more detectors; c. a system which is configured to run an algorithm for determining the location of the air cell of the egg and the preferred extraction point; and d. a system for positioning the egg relative to an extractor or an egg opener or vice versa from their initial position to the preferred extraction point.

The present invention relates to a computer-controlled system for non-invasively identifying the location of the air cell of an egg and determining a preferred extraction point relative to the position of the air cell of the egg, the system comprising: a. an egg manipulator to hold and orient one or more eggs in a defined position; b. a candling unit comprising one or more light sources and one or more detectors; c. a system which is configured to run an algorithm for determining the location of the air cell of the egg and the preferred extraction point; and d. a system for positioning the egg relative to an extractor or an egg opener or vice versa from their initial position to the preferred extraction point.

An egg orientation device is adapted to put eggs (10, 10′) point down or point up in egg retainers (6). The egg orientation device comprises a stationary lane having a support plate (2) comprising a central zone (3) and two lateral zones (4). The device furthermore comprises a pusher (20) movable in a conveying direction along the lane and adapted to push an egg such that it rolls over the support plate around its longitudinal axis. An egg retainer is movable in the conveying direction beneath the support plate of the lane in a synchronised manner with the pusher. At least one drop opening (5, 7A, 7B) is provided in the support plate, which allows eggs to fall through and drop point down or point up in the egg retainer that is positioned underneath the drop opening. The drop opening is located in the central zone or in at least one of the lateral zones for dropping the eggs in the egg retainer point up and point down respectively.

An egg orientation device is adapted to put eggs (10, 10′) point down or point up in egg retainers (6). The egg orientation device comprises a stationary lane having a support plate (2) comprising a central zone (3) and two lateral zones (4). The device furthermore comprises a pusher (20) movable in a conveying direction along the lane and adapted to push an egg such that it rolls over the support plate around its longitudinal axis. An egg retainer is movable in the conveying direction beneath the support plate of the lane in a synchronised manner with the pusher. At least one drop opening (5, 7A, 7B) is provided in the support plate, which allows eggs to fall through and drop point down or point up in the egg retainer that is positioned underneath the drop opening. The drop opening is located in the central zone or in at least one of the lateral zones for dropping the eggs in the egg retainer point up and point down respectively.

The system for managing bird populations includes a drone; a disruptor comprising an extension arm having a proximal end and a distal end, the proximal end being operatively coupled with the drone, and the distal end comprising a tool portion, where the tool portion comprises a piercing element constructed for engagement with one or more eggs in a nest; and a remote control system. The remote control system may comprise one or more remote control units and a monitor.

The system can be used to manage bird populations by flying the drone above a bird's nest; positioning the drone above the bird's nest; and descending the drone to disrupt eggs in the bird's nest with the disruptor.

The system for managing bird populations includes a drone; a disruptor comprising an extension arm having a proximal end and a distal end, the proximal end being operatively coupled with the drone, and the distal end comprising a tool portion, where the tool portion comprises a piercing element constructed for engagement with one or more eggs in a nest; and a remote control system. The remote control system may comprise one or more remote control units and a monitor.

The system can be used to manage bird populations by flying the drone above a bird's nest; positioning the drone above the bird's nest; and descending the drone to disrupt eggs in the bird's nest with the disruptor.

An egg printing system comprises a printer (30, 31, 32) and an endless egg conveyor (1) that is adapted to move the eggs (50) past the printer. The conveyor including an endless element running around a set of rotational wheels and a drive unit defining a conveying direction of the conveyor. The egg conveyor includes a lane of egg retaining pockets (10) coupled to the endless element, said lane of retaining pockets in use moving in the conveying direction. Each retaining pocket has a central axis and an upper receiving opening to receive an egg with a longitudinal axis of the egg generally aligned with said central axis of the pocket. The pocket has a side opening at a side thereof facing in the conveying direction and/or in the opposite direction, leaving a side surface area exposed of the egg that is received in the pocket. The retaining pockets remain in an upright position in every position in the lane. The printer is positioned at one of the head sections of the conveyor with a printing head facing the corresponding lane being directed to said side opening in the pocket to allow printing on said side surface area of the egg.

Disclosed is a device for the automatic removal of rejected eggs from an incubation tray, whereby the device includes a suction power above the egg to suck up the egg, and the device further includes a blowing power against the bottom of the egg to blow away the egg, whereby the blowing power blows an air flow or overpressure against the bottom of the egg. Also disclosed is a method for the automatic removal of one or more rejected eggs from an incubation tray.