A robotic arm maneuvers a teat preparation cup and executes instructions from a robotic arm controller. The controller comprises an interface, a memory, and a processor. The processor instructs the sensor to perform a first scan. If the first scan discovers a first set of teats, the processor moves the robotic arm a first distance and instructs the sensor to perform a second scan. If the second scan discovers a second set of teats, the processor moves the robotic arm to a location under the first teat, and instructs the sensor to perform a third scan. The processor determines if the third scan discovers a third set of teats. If each of the first set, second set, and third set of discovered teats comprises the first teat, the processor instructs the robotic arm to attach the preparation cup to the first teat.

A system comprising a robotic arm, a plurality of grabbers, a sensor, and a preparation cup. The robotic arm has a first end and a recessed portion. The grabbers are coupled to the robotic arm at the first end. The sensor is positioned inside the recessed portion of the robotic arm at a first distance from the first end and at a first angle. The preparation cup is coupled to wings having a body portion, a first extended portion, and a second extended portion. The body portion is coupled to a portion of the preparation cup, the first extended portion extends in a first direction and the second extended portion extends in a second direction. The wings are operable to be magnetically coupled to the plurality of grabbers via the first and second extended portions.

A milking system that includes milking cups, a milking robot with a robot arm configured to attach each of the milking cups to a respective teat, a sensor that detects two adjacent teats, and a control arrangement communicatively connected to the sensor (160) and the robot arm, where the control arrangement is configured to determine a distance between the two adjacent teats, select one of the two adjacent teats to commence attachment of a first milking cup if the distance fulfils a distance criterion, and generate a command to the robot arm to commence the milking cup attachment to the selected teat.

A system comprises a memory operable to store first light intensity information for a first pixel of an image that includes a dairy livestock, and second light intensity information for a second pixel of the image. The system further comprises a processor communicatively coupled to the memory and operable to determine that a difference between the first light intensity information and the second light intensity information exceeds a threshold, and discard one of the first pixel or the second pixel from the image. The system further includes a robotic attacher configured to position milking equipment relative to the dairy livestock based at least in part upon the light intensity image, excluding the discarded pixel

An implement for keeping dairy animals, provided with a first and a second production unit and with a care unit having a plurality of subunits, wherein each production unit is provided with at least one accommodation area for a production group, which comprises a group of lactating dairy animals, and with a milking implement for milking the production group, wherein the subunits of the care unit at least include a calving unit for separately accommodating dairy animals in a calving period, and a milking implement for milking newly calved dairy animals, and an infirmary unit for separately accommodating sick animals, and wherein the care unit forms a connection between the production units. There is thus provided a compact disposition, comprising efficient and short distances, for dairy animals requiring care.

A device for automatically milking an animal in an animal space is provided with a robot arm for automatically performing an action on a teat of the animal, a teat sensor, and an animal position sensor for determining the animal position in the animal space. The animal position sensor is movable in a longitudinal direction of the animal space. The animal position sensor is mounted so as to be movable or shiftable in a longitudinal direction of the animal space. This has the advantage that the range of the sensor becomes considerably larger while the sensor can be the same as in a known device.

A method includes housing a dairy livestock in a stall portion of a milking box and retrieving, by a robotic attacher, a cup. For each of a plurality of teats of a dairy livestock, the method further uses the robotic arm to perform the steps of attaching the cup to the teat, detaching the cup from the teat, and maintaining the cup within the stall portion of the milking box from the time that the cup is attached to the first teat of the dairy livestock through the time that the cup is attached to a last teat of the dairy livestock. The method concludes by retracting the cup into an equipment area of the milking box after detaching the cup from the last teat of the dairy livestock.

A voluntary milking system and method for treating dairy livestock having fore legs and hind legs, wherein the system comprises milking stalls voluntarily accessible to animals that are milked by mobile units configured to travel between the fore and hind legs of the animal.

A milking cluster pipe support (1) for fitment to the deck-side (3) of a milking parlour comprising a pivotable elongate pipe support arm (5) having pipe slots (29) and which is moveable about a pivot (7) between a deployed and a stowed position within a plane P. The pipe support arm (5) is pivotable in a first rotational sense from its deployed position to its stowed position and in a second rotational sense from its stowed position to its deployed position, wherein the first and second rotational senses are opposite to each other. The pipe support arm (5) has a centre of gravity which is located on one side of the vertical axis Y-Y in the deployed position and on the other side of the vertical axis Y-Y in the stowed position.

A position-determining device, and a milking device, that determines a relative position of an object and includes a 3D time-of-flight camera with a 2D arrangement of pixels configured to repeatedly record an image of a space. A control unit is connected and includes an image-processing device. The 3D time-of-flight camera has a controllable light source and is configured to record a 2D image by means of reflected emitted light and collect distance information. The image-processing device is configured to recognize an object in the 2D image using image-processing criteria and determine distance information and relative position by analysing the 2D image and the distance information. Due to the fact that distance information, which is often much more noisy than 2D brightness information, can be determined with far fewer image points, the position is determined more quickly and reliably.