A diagnostic apparatus for testing a milking point of a milking machine includes sensors for measuring fluid-transport related parameters, including various pressure levels and/or flow values relating to a set of teatcups includes a controllable valve and a set of test tubes. Each test tube is configured to be attached to one teatcup, where the controllable valve selectively arranges a particular one of the test tubes for measurement of at least one parameter via one of the sensors in response to a control signal. The measurements are performed while all the teatcups are simultaneously attached to the test tubes and an external vacuum pressure is applied either on a milk-line side of the controllable valve or on a side opposite to the milk-line side relative to the controllable valve.

A method includes positioning a robotic attacher under a dairy livestock located in a milking stall, wherein the robotic attacher comprises a nozzle. The method continues by rotating the robotic attacher such that the nozzle is positioned generally on the top of the robotic attacher and performing a spraying operation using the nozzle. The method concludes by retracting the robotic attacher from under the dairy livestock.

A method for applying disinfectant to the teats of a dairy livestock comprises moving a robotic arm along a track in relation to a rotary milking platform housing a dairy livestock and independent of any physical coupling between the robotic arm and the rotary milking platform. The rotary milking platform has a substantially circular perimeter. The track is positioned outside the perimeter of the rotary milking platform. At least a portion of the track is straight and offset in relation to the rotary milking platform. The robotic arm comprises an arm member operable to pivot about an axis that is parallel to the track, and a spray tool attached to one end of the arm member. The method further comprises extending the robotic arm between the hind legs of the dairy livestock while the rotary milking platform rotates such that the spray tool is located at a spray position from which it may discharge disinfectant to the teats of the dairy livestock.

A method for applying disinfectant to the teats of a dairy livestock comprises moving a robotic arm along a track in relation to a rotary milking platform housing a dairy livestock and independent of any physical coupling between the robotic arm and the rotary milking platform. The rotary milking platform has a substantially circular perimeter. The track is positioned outside the perimeter of the rotary milking platform. At least a portion of the track is straight and offset in relation to the rotary milking platform. The robotic arm comprises an arm member operable to pivot about an axis that is parallel to the track, and a spray tool attached to one end of the arm member. The method further comprises extending the robotic arm between the hind legs of the dairy livestock while the rotary milking platform rotates such that the spray tool is located at a spray position from which it may discharge disinfectant to the teats of the dairy livestock.

A safety valve device for a milking installation for milking milk-producing animals having a first valve with a first port and with a first port connector, a second valve with a second port and with a second port connector, a third valve with a third port and a third port connector, a drive, a common actuator, and at least one valve spring, and arranged so that the first port connector of the first valve is in fluid communication with the second port connector of the second valve, and the safety valve device can be moved between a first switching position, in which the first valve and the second valve are closed in order to block the first port and the second port and the third valve, is open a transition position, in which the first valve, the second valve and the third valve are closed, and a second switching position, in which the first valve and the second valve are open to connect the first port to the second port and the third valve is closed to block the third port.

A safety valve device for a milking installation for milking milk-producing animals having a first valve with a first port and with a first port connector, a second valve with a second port and with a second port connector, a third valve with a third port and a third port connector, a drive, a common actuator, and at least one valve spring, and arranged so that the first port connector of the first valve is in fluid communication with the second port connector of the second valve, and the safety valve device can be moved between a first switching position, in which the first valve and the second valve are closed in order to block the first port and the second port and the third valve, is open a transition position, in which the first valve, the second valve and the third valve are closed, and a second switching position, in which the first valve and the second valve are open to connect the first port to the second port and the third valve is closed to block the third port.

A system comprises a milking box, a robotic attacher, a sensor, and a controller. The milking box has a stall to accommodate a dairy livestock. The stall comprises a first exit gate on a first side of the stall leading to a first sorting region and a second exit gate on a second side of the stall leading to a second sorting region. The robotic attacher extends from the rear between the hind legs of the dairy livestock. The sensor identifies the dairy livestock within the milking box stall. The controller selects and opens the first exit gate or the second exit gate based at least in part upon the identity of the dairy livestock.

A system comprises a milking box, a robotic attacher, a sensor, and a controller. The milking box has a stall to accommodate a dairy livestock. The stall comprises a first exit gate on a first side of the stall leading to a first sorting region and a second exit gate on a second side of the stall leading to a second sorting region. The robotic attacher extends from the rear between the hind legs of the dairy livestock. The sensor identifies the dairy livestock within the milking box stall. The controller selects and opens the first exit gate or the second exit gate based at least in part upon the identity of the dairy livestock.

A system that includes a three-dimensional (3D) camera configured to capture a 3D image of a rearview of a dairy livestock in a stall and a processor. The processor is configured to obtain the 3D image, identify one or more regions within the 3D image comprising depth values greater than a depth value threshold, and s to identify a thigh gap region from the one or more regions. The processor is further configured to demarcate an access region within the thigh gap region and demarcate a tail detection region. The processor is further configured to identify one or more tail candidates within the tail detection region, to identify a tail candidate that corresponds with a tail model as the tail, and to determine position information for the tail.

A system that includes a three-dimensional (3D) camera configured to capture a 3D image of a rearview of a dairy livestock in a stall and a processor. The processor is configured to obtain the 3D image, identify one or more regions within the 3D image comprising depth values greater than a depth value threshold, and s to identify a thigh gap region from the one or more regions. The processor is further configured to demarcate an access region within the thigh gap region and demarcate a tail detection region. The processor is further configured to identify one or more tail candidates within the tail detection region, to identify a tail candidate that corresponds with a tail model as the tail, and to determine position information for the tail.