A method for milking a dairy animal with a robot milking device including a teat position determination system and a controller. The method includes allowing the robot milking device, with the help of the teat position determination system, to make one or more connection attempts for connecting at least one milking cup to a teat of the dairy animal, and milking with all connected milking cups where the controller records a number of failed connection attempts. The number of failed connection attempts #MA in a predefined number of milkings, which number of milkings is at least equal to a predefined number #MB, fulfils a predefined criterion, automatically adapting the milking criterion by means of the controller.

In picking up tools in an automatic milking arrangement, the positions of the tools are determined by registering, via a camera at an origin location, three-dimensional image data representing the tools whose positions are to be determined. Using an algorithm involving matching the image data against reference data, tool candidates are identified in the three-dimensional image data. A respective position is calculated for the tools based on the origin location and data expressing respective distances from the origin location to each of the identified tool candidates. It is presumed that the tools have predefined locations relative to one another. Therefore, any second tool candidate is disregarded, which is detected at a separation distance from a first tool candidate when the separation distance exceeds a first threshold distance in relation to the predefined relative locations.

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 cluster used for milking a dairy animal in a milking parlor, the milking cluster including a teat cup unit, a teat cup, a drive device, a hose arrangement joined to the teat cup, a hose guide engaging the hose arrangement, and the hose guide includes a plurality of hose-engaging rollers.

A gripping device for a robotic manipulation device that grips and attaches teat cups to an animal. The gripping device for each teat cup to be gripped and attached includes a holding member configured to releasably hold a teat cup, and a power member configured to move the holding member from a base position (p1) to a raised position (p2) in which the teat cup can be attached to a teat. The gripping device for each teat cup to be gripped and attached includes a movable cover portion movably arranged between a covering position, in which it covers the opening of the teat cup, and a non-covering position, in which the opening of the teat cup is exposed. When power member lifts the holding member from the base position to the raised position, the movable cover portion moves from the covering position to the non-covering position.

A system for milking a group of animals, in particular cows, comprising an accommodation space in which the animals roam freely, and a plurality of fixed milking stations. A milk storage tank is placed outside the accommodation space. An automatic milking system for automated milking of the animals comprises at least one autonomous self-propelled trolley with milking cups. The milking system automatically connects the milking cups of the trolley to the teats of the animal. A milk discharge system connects the milking cups to the milk storage tank. The milk discharge system comprises flexible milk lines which are connected to the trolley. The trolley is connected to each milking station through a connection in an animal-free space adjacent to the milking stations. The flexible milk line is configured so the trolley can travel from the animal-free space into each of the milking stations while connected to the trolley.

A milking robot for automated milking of milking animals, comprising a cylinder supporting movement of at least one movable component. The cylinder has a wall with a ventilation opening and a cylinder rod which can move in and out of the cylinder. The cylinder wall surrounds at least one variable volume part for movement of the cylinder rod. The opening configures the cylinder to remain in virtual pressure equilibrium with an environment. A gas capture device is connected which has a variable volume and which together with the variable volume part, forms an air-tight gas volume. Thus the variable volume part is kept at almost ambient pressure, so that no unnecessary counter-pressure occurs in the cylinder, during extension and retraction of the cylinder rod. Also less to no exchange of gas and dirt with the environment can take place for longer life and better reliability of the cylinder.

A system for controlling the position of a robot carriage includes a linear carriage track positioned adjacent to a rotary milking platform, a robot carriage positioned on the carriage track such that the robot carriage may move along the carriage track, and a controller. The controller determines a rotational movement of a milking stall of the rotary milking platform, and determines a linear movement of the robot carriage on the carriage track corresponding to the rotational movement of the milking stall of the rotary milking platform. The controller further communicates a signal to a carriage actuator coupled to the robot carriage and the carriage track. The signal causes the carriage actuator to move the robot carriage along the carriage track according to the determined linear movement as the rotary milking platform rotates.

A system includes a robotic arm, an imaging device coupled to the robotic arm, a tail positioner 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 tail positioner is able to move from a down position to an up position. The processor is coupled to both the imaging device and the tail positioner 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 tail positioner from the down position to the up position, thereby moving the tail out of the field of view of the imaging device.

A system includes a robotic arm and a controller. The controller accesses a first image and a second image generated by a first camera. The controller determines a reference point based at least in part on the first image. The controller determines a position of a teat of the dairy livestock based at least in part on the second image. The controller instructs the robotic arm to grip a milking cup and move it towards the determined position of the teat between the hind legs of the dairy livestock from the rear. The controller then instructs the robotic arm to release the milking cup, to move in an upward direction towards an udder of the dairy livestock, and to move away from the teat.