A robotic attacher includes an arm that extends between the legs of a dairy livestock and a gripping portion coupled to the arm. The gripping portion is operable to rotate such that at a first time, a nozzle is positioned generally on the bottom of the gripping portion, and at a second time, the nozzle is positioned generally on the top of the gripping portion.

A system and method for automatically drying-off a machine-milked dairy animal by controlling milk production during a gradual drying-off period. During the gradual drying-off period, the dairy animal is not milked out. For each milking during this period, an amount of milk to be removed is determined, which is less than the amount removed at a previous milking. When the amount of milk for the current milking has been removed from the dairy animal, milking is stopped. The start of the gradual drying-off period is calculated from the dry-off date, the desired date of cessation of milking for this lactation, and from a predetermined drying-off period.

A system and method for automatically drying-off a machine-milked dairy animal by controlling milk production during a gradual drying-off period. During the gradual drying-off period, the dairy animal is not milked out. For each milking during this period, an amount of milk to be removed is determined, which is less than the amount removed at a previous milking. When the amount of milk for the current milking has been removed from the dairy animal, milking is stopped. The start of the gradual drying-off period is calculated from the dry-off date, the desired date of cessation of milking for this lactation, and from a predetermined drying-off period.

Embodiments are directed to a sealed gear housing for a hand-held applicator for cleaning a teat of a milk-producing animal. In an embodiment, a first portion of the housing has a plurality of gear holes and a peripherally extending flange surrounding the gear holes. A second portion has a motor mount and having a peripherally extending groove in which the flange of the first portion fits, the first and second portions each have at least one delivery port configured to be coupled to an at least one disinfectant delivery line.

Embodiments are directed to a sealed gear housing for a hand-held applicator for cleaning a teat of a milk-producing animal. In an embodiment, a first portion of the housing has a plurality of gear holes and a peripherally extending flange surrounding the gear holes. A second portion has a motor mount and having a peripherally extending groove in which the flange of the first portion fits, the first and second portions each have at least one delivery port configured to be coupled to an at least one disinfectant delivery line.

A system for cleaning a dairy animal milker unit and applying dip to a dairy animal, the system includes a main control, an air supply, a water supply, a backflush fluid supply, a dip supply, a stall control for receiving the air, water, backflush fluid and dip supplies, and a safety valve that is adjacent to a downstream portion of the milker unit to control backflush and dip fluids being fed to the milker unit.

A system for cleaning a dairy animal milker unit and applying dip to a dairy animal, the system includes a main control, an air supply, a water supply, a backflush fluid supply, a dip supply, a stall control for receiving the air, water, backflush fluid and dip supplies, and a safety valve that is adjacent to a downstream portion of the milker unit to control backflush and dip fluids being fed to the milker unit.

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 in order to direct the first dairy livestock into either the first sorting region or the second sorting region.

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 in order to direct the first dairy livestock into either the first sorting region or the second sorting region.

A system for operating a robotic arm, comprises a controller and a robotic arm. The controller accesses an image of the rear of dairy livestock located in a stall of a rotary milking platform and, in conjunction with the stall of the rotary milking platform in which a dairy livestock is located moving into an area adjacent a robotic arm, determines whether a milking cluster is attached to the dairy livestock based at least in part upon the image. The robotic arm is communicatively coupled to the controller and extends between the legs of the dairy livestock if the controller determines that the milking cluster is not attached to the dairy livestock. The robotic arm does not extend between the legs of the dairy livestock if the controller determines that the milking cluster is attached to the dairy livestock.