An antiinfective-free formulation for prophylactic treatment of mastitis in dry cows comprises a seal formulation having approximately 65% by weight of bismuth sub-nitrate in a gel based on aluminium stearate. The seal formulation is prepared by adding the bismuth sub-nitrate to the gel base in at least two separate stages.

A system includes a milking stall to accommodate a dairy livestock and a robotic attacher. The robotic attacher extends under the dairy livestock and comprises a nozzle. The robotic attacher is operable to rotate such that, during a first operation, the nozzle is positioned generally on the bottom of the robotic attacher, and during a second operation, the nozzle is positioned generally on the top of the robotic attacher.

A system includes a milking stall to accommodate a dairy livestock and a robotic attacher. The robotic attacher extends under the dairy livestock and comprises a nozzle. The robotic attacher is operable to rotate such that, during a first operation, the nozzle is positioned generally on the bottom of the robotic attacher, and during a second operation, the nozzle is positioned generally on the top of the robotic attacher.

A robotic attacher comprises a gripping portion, a vision system positioned on a first surface of the gripping portion, and at least one nozzle positioned on a second surface of the gripping portion. The gripping portion is rotates about a longitudinal axis such that during a first time, the vision system is positioned generally on the top of the gripping portion, and during a second time, the nozzle is positioned generally on the top of the gripping portion.

A robotic attacher comprises a gripping portion, a vision system positioned on a first surface of the gripping portion, and at least one nozzle positioned on a second surface of the gripping portion. The gripping portion is rotates about a longitudinal axis such that during a first time, the vision system is positioned generally on the top of the gripping portion, and during a second time, the nozzle is positioned generally on the top of the gripping portion.

A system for operating a robotic arm comprises a carriage and a robotic arm. The carriage is mounted on a track adjacent to a rotary milking platform having a substantially circular perimeter and a stall for a dairy livestock. The carriage moves along a substantially straight portion of the track tangent to and outside the perimeter of the rotary milking platform at a rate based at least in part upon a speed of rotation of the rotary milking platform. The carriage moves in a direction corresponding to the direction of rotation of the rotary milking platform and such movement of the carriage is independent of any physical coupling between the carriage and the rotary milking platform. The robotic arm extends between the legs of the dairy livestock.

A system for operating a robotic arm comprises a carriage and a robotic arm. The carriage is mounted on a track adjacent to a rotary milking platform having a substantially circular perimeter and a stall for a dairy livestock. The carriage moves along a substantially straight portion of the track tangent to and outside the perimeter of the rotary milking platform at a rate based at least in part upon a speed of rotation of the rotary milking platform. The carriage moves in a direction corresponding to the direction of rotation of the rotary milking platform and such movement of the carriage is independent of any physical coupling between the carriage and the rotary milking platform. The robotic arm extends between the legs of the dairy livestock.

A system includes a camera, a controller and a robotic arm. The camera generates an image of an udder of a dairy livestock. The controller determines a position of the udder of the dairy livestock based at least in part upon the image. The controller further determines a spray position based at least in part upon the determined position of the udder of the dairy livestock. Determining the spray position includes processing the accessed image to determine a tangent at the rear of the udder and a tangent at the bottom of the udder. The spray position is a position relative to the intersection of the two tangents. The robotic arm is communicatively coupled to the controller and positions a spray tool at the spray position.

A system includes a camera, a controller and a robotic arm. The camera generates an image of an udder of a dairy livestock. The controller determines a position of the udder of the dairy livestock based at least in part upon the image. The controller further determines a spray position based at least in part upon the determined position of the udder of the dairy livestock. Determining the spray position includes processing the accessed image to determine a tangent at the rear of the udder and a tangent at the bottom of the udder. The spray position is a position relative to the intersection of the two tangents. The robotic arm is communicatively coupled to the controller and positions a spray tool at the spray position.

The present invention relates to preparing dairy animal teats for being milked, and more particularly to teat preparation, rinsing, and milking that all take place in a milking machine teat cup liner. Such a method includes: applying a teat sanitizer to the teat; injecting air into the liner to force the teat sanitizer toward a waste milk line connected to the liner; pulsating the liner at a first pulsation rate; drawing a rinsing milk from the teat; directing the teat sanitizer, the air, and the rinsing fluid to the waste milk line; pulsating the liner at a second pulsation rate to draw additional milk from the teat; and directing the additional milk to a good milk line.