In order to avoid negative changes in the teat ends of a cow, in particular to avoid hyperkeratoses, the invention proposes a method for operating a milking system in which at least one of the parameters from total pressure per cycle, minimum total pressure per cycle or the ratio of total suction to total pressure is determined for at least one animal of a herd during at least one part of a milking process, and is compared with at least one reference value.

A milk sampling device includes a housing forming an inner space, an inlet opening to the inner space, a deflector member with an upper surface mounted in the inner space of the housing in a position vertically below the inlet opening, a flow passage formed between a periphery edge portion of the deflector member and an inner surface of the housing, and a milk sampling passage provided with an opening which constitutes a part of the flow passage. The upper surface of the deflector member comprises a plurality of a upwardly extending members arranged at a distance from each other in the vicinity of the periphery edge portion of the deflector member such that flow channels are formed between adjacent upwardly extending members.

A milking device includes a support device (1) supporting a milking member (2) having a claw (3) and a number of teatcups (4) to be attached to a respective teat of an animal. The support device (1) includes a rear portion (6), an attachment part (9) attaching the support device to a structure, and an arm section (7) having a proximal end portion attached to the rear portion (6) and a distal end portion movable between an active position in the proximity of the animal to be milked and a rest position. A first cavity extends along the arm section and houses a retracting member for retracting the milking member from the teats of the animal. A second cavity for conveying a fluid flow extends along the arm section. The arm section includes an extruded part enclosing the first cavity and the second cavity.

A distribution unit for milk samples that includes a first distribution portion with a first flow channel and a plurality of ports adjoining and communicating with the first flow channel, the ports configured to permit various media to be delivered to and from the first flow channel, and a second distribution portion that includes a second flow channel and a plurality of ports adjoining and communicating with the second flow channel, including at least a milk inlet port permitting milk to be delivered from the first flow channel to the second flow channel, and including a milk outlet port permitting milk samples to be delivered from the second flow channel to a further milk analyzing unit.

A milking arrangement includes a milking machine for milking an animal, where the milking arrangement includes an analysing unit configured to determining a value of haptoglobin quantity in a milk sample taken from milk harvest by the milking machine. The analysing unit including a haptoglobin sensor device configured to provide a value of haptoglobin quantity in the milk sample.

Disclosed is a system for treating dairy livestock having fore legs and hind legs, wherein the system comprises a milking parlor ramp, livestock stalls positioned along at least part of the 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 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 milking parlor ramp, livestock stalls positioned along at least part of the 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 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 milking system includes a milking apparatus for milking of dairy animals, and a plurality of wearing parts, inclusive of teat liners and/or milk lines and/or pulsation lines. The system further includes a computer system configured to control and/or monitor the milking apparatus, and to generate a signal which indicates that one of the wearing parts should be replaced and provides a characterization of that wearing part. The milking system further includes a 3D printer operatively connected to the computer system and configured to print the characterized part on the basis of the generated signal. Thus it is not necessary to keep an unnecessarily large stock of spare parts, but it becomes possible to directly provide the spare parts quickly, cheaply and with less chance of errors. Moreover, it is thus possible to tailor the parts, especially teat liners, to animals.

A milking system includes an assembly, a controller, and a milking cluster configured to attach to one or more teats of a livestock. The assembly includes a clevis, a piston, a pulley system, and a sensor. The clevis includes a first member, a second member, a base member, and a cylinder. The cylinder is coupled to the base member. The piston is positioned at least partially within the cylinder, and is configured to move within the cylinder. The pulley system of the assembly includes a cord configured to be coupled to the milking cluster. The assembly includes a sensor configured to generate a displacement signal in response to detecting that a portion of the clevis is within a predefined distance of the sensor.

A milking robot includes a movable arm having a first end that couples to a frame and a free extremity at a second end that extends telescopically in a longitudinal direction. The milking robot further includes at least one gripper coupled to the free extremity of the movable arm at the second end, wherein the gripper is extendable away from the movable arm in the longitudinal direction based at least in part upon the telescopic extension of the free extremity.