Disclosed is a system for treating dairy livestock having fore legs and hind legs, wherein the system comprises a milking parlor ramp, livestock stalls positioned along at least part of the milking parlor ramp, wherein each stall is configured to contain one dairy livestock, at least one vertical upright teat cup holder comprising teat cups and a mobile unit. The mobile unit comprises equipment for treating livestock and a processor, where the mobile unit is configured to travel between the fore legs and hind legs of the dairy livestock on the milking parlor ramp and use the equipment to perform at least one action related to a treatment of the dairy livestock. Also disclosed is that the equipment includes an arm configured to withdraw the teat cups from the vertical upright teat cup holder and connect them to the dairy livestock.

This invention is related to a double grab, its rinsing cup and milking machine provided therewith, and the method for automatically applying teat cups to the teats of an udder of an animal to be milked. The double grab according to the invention includes:a first housing part provided with a first magnet designed to hold a first teat cup;a second housing part, installed substantially in a horizontal plane next to the first housing part, provided with a second magnet designed to hold a second teat cup;whereby each housing part is provided with separate pivoting means that can be activated and is designed to make the related housing part pivot around a pivoting axis which in use, extends substantially in a horizontal direction, substantially in a widthwise direction of the arm.

A milking robot includes a movable arm having a first end that couples to a frame and a free extremity at a second end that extends telescopically in a longitudinal direction. The milking robot further includes at least one gripper coupled to the free extremity of the movable arm at the second end, wherein the gripper is extendable away from the movable arm in the longitudinal direction based at least in part upon the telescopic extension of the free extremity.

A system includes a robotic arm positioned in an equipment area of a milking box that includes a stall portion housing a dairy livestock with four teats. The robotic arm retrieves a cup, and for a plurality of teats of the dairy livestock, the robotic arm attaches the cup to a teat, detaches the cup from the teat, and maintains the cup within the stall portion of the milking box from the time that the cup is attached to a first teat of the dairy livestock through the time that the cup is attached to a last teat of the dairy livestock. The cup is retracted into the equipment portion of the milking box after it is detached from the last teat of the dairy livestock.

A milking device includes a mounting with four milking cups detachably fitted thereto, a robot arm for displacing the mounting from a rest position in the direction of an udder of a dairy animal, and a control system for the robot arm. The milking cups are each connected with a milk line connection to a milk line so that once the milking cups are fitted to the mounting, a first pair of the milk line connections extend in parallel in a first direction, and another pair of the milk line connections extend in parallel in a second direction, which first and second directions are parallel to a vertical plane and vertical projections of the first direction and the second direction onto a horizontal plane are oppositely directed. As a result, milking cups can be provided very compactly on the mounting without the milk lines lying in the way of one another, for example in the connection process. The mounting can therefore be narrow brought through between the hind legs of a dairy animal with less chance of touching the hind legs.

A system includes a robotic arm, an imaging device coupled to the robotic arm, a board coupled to the robotic arm, and a processor. The imaging device captures imaging data of a rearview of a dairy livestock through a field of view of the imaging device. The board is able to pivot from a down position to an up position and has an aperture through which the imaging device can pass through when the board lowers from the up position to the down position. The processor is coupled to both the imaging device and the board and is configured to identify a tail of the dairy livestock within the imaging data captured by the imaging device and send one or more instructions to raise the board from the down position to the up position, thereby moving the tail out of the field of view of the imaging device.

A milking robot for the fully automatic milking of dairy animals includes at least one moving component and a cylinder configured to support a movement of the component. The cylinder has a cylinder wall having an aeration opening, as well as a cylinder rod slidable into and out of the cylinder. The cylinder wall surrounds at least one variable volume part, which volume part is free from pressure fluid connections for displacement of the cylinder rod. The cylinder is configured to remain, via the opening, substantially in pressure equilibrium with an environment of the cylinder. To the cylinder wall around the aeration opening is connected a gas collecting device which has a changeable volume and which, together with the variable volume part, forms an airtight gas volume. In addition, the gas collecting device has a minimum volume greater than zero.

A milking robot comprises a movable arm having a length in a longitudinal direction, and at least one gripper swivably mounted to the movable arm such that it moves between a first position parallel to the movable arm's longitudinal direction and a second position at which the gripper extends sideways in a horizontal plane away from the movable arm's longitudinal direction.

A robotic attacher comprises a main arm, a supplemental arm coupled to the main arm, and a gripping portion coupled to the supplemental arm. The supplemental arm moves in an x-direction and a y-direction. The gripping portion moves in a first z-direction in relation to the supplemental arm. The gripping portion also moves in a second z-direction opposite the first z-direction in relation to the supplemental arm.

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