A rotary dairy cow milking platform that rotates about a rotational axis and has a plurality of pre-fabricated moulded bail floor defining modular components 1-10 and a supporting substructure 12, 13 14. Each modular component is detachable from the substructure and has been pre-formed independently of any components from the substructure. Each modular component is also totally or at least in part formed from a fibre reinforced resin based composite material. The modular components each have a mould defined rigid exoskeleton 34 wrapped about an inlay or an imbedded core 33 of another material moulded within the exoskeleton. The end peripheries of the modular components are substantially radially aligned with respect to the axis of rotation of the milking platform. Further, the modular components have been assembled onto the substructure to form a substantially annular deck of the milking platform.

Disclosed is a system for treating dairy livestock having fore legs and hind legs, wherein the system comprises a parallel milking parlor ramp, livestock stalls positioned along at least part of the parallel 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 parallel 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.

Disclosed is a system for treating dairy livestock having fore legs and hind legs, wherein the system comprises a parallel milking parlor ramp, livestock stalls positioned along at least part of the parallel 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 parallel 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.

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 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 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.

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.

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 comprises a robotic arm, camera, and a controller. The camera is positioned on a surface of the robotic arm and emits a laser signal at an upward, non-zero angle relative to a longitudinal axis of the robotic arm. The controller instructs the robotic arm to grip a milking cup, and determines a position of a teat of the dairy livestock based at least in part upon the non-zero angle of the laser signal emitted by the camera. The controller instructs the robotic arm to move the milking cup towards the determined position of the teat between the hind legs of the dairy livestock from the rear, release the milking cup in response to the milking cup being attached to the teat. move in an upward direction towards an udder of the dairy livestock in conjunction with the robotic arm releasing the milking cup, and to move away from the teat.