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 safety valve arrangement and method, having an upstream block valve, a downstream block valve, and a pressure monitored galley between the upstream valve and the downstream valve.

Animal milking claws, assemblies, and methods of making and using same. Upper and lower claw portions, the upper claw portion having front and rear milk inlets, and the lower claw portion including a milk outlet. Milk inlets positioned generally tangentially to the upper claw portion force milk to flow on geodesic curves on the internal surface of the upper milk claw. Milk is forced to impact upon the vertical partition in the lower claw portion. The milk outlet has a reinforced portion extending at least a portion of a length of the milk outlet, with one or more reinforcing chamfers where the reinforced portion connects with the lower claw portion. Coolant for heat transfer may be provided to the milk outlet or the lower claw portion, or both.

A milking system equipped with teat cups each connected to a respective milk evacuation tube, a vacuum pump, a milk tank, vacuum regulators configured to control a vacuum pressure level prevailing in the teat cup, vacuum pressure sensors each configured to measure vacuum pressure level prevailing under one of the teats, an animal identification sensor, a database, a processing device configured to: determine animal ID, extract data of each respective teat from the database, determine a teat specific vacuum pressure level at each teat, and generate a command to each vacuum regulator, to set the teat specific vacuum pressure level at each teat cup.

A space divider of a milking parlor arrangement for at least one milking parlor for milking milk-producing animals, wherein the space divider is arranged approximately parallel to a longitudinal axis of the animal to be milked, has an arm device having a milking cluster, which can be adjusted from a parking position to a working position and back. The arm device is arranged with the milking cluster in the parking position in the space divider and can be adjusted into the working position laterally to the animal to be milked between the front and rear legs thereof in fully automatic operation or semiautomatic operation. The space divider is designed in such a way that no additional space is required between adjacent animals, so that many animals can be milked in a milking parlor arrangement while the smallest possible amount of space is required.

A cassette (130) configured to enable measurement of at least one biomarker value of a milk sample of an animal (100). The cassette (130) includes a tape distributing spool (131); a tape (170) with a plurality of dry sticks (180a, 180b, 180c), configured to indicate the biomarker value of the milk sample, and a top film (310) arranged to protect the dry sticks (180a, 180b, 180c) while rolled up on the tape distributing spool (131); a tape collecting spool (132), configured to collect used dry sticks (180a, 180b, 180c); and a top film reel (330), arranged to peel off and collect the top film (310) of the tape (170).

A milking system includes a milking device, and a milk storage system having: a temporary milk storage vessel for temporarily storing milk from a plurality of milking operations, a milk pipe from the milking device to the temporary milk storage vessel, a milk tank for storing the milk from the temporary milk storage vessel, a control unit, a main milk pipe from the temporary milk storage vessel to the milk tank, a pressurized liquid supply which is controllable by the control unit and is provided and configured to supply a pressurized liquid, other than milk, to the milk storage system, a first and a second discharge provided on the main milk pipe, a selection device which is controllable by the control unit and is on the main milk pipe towards the first discharge or the second discharge, wherein the control unit is configured to perform a milk transferring action for transferring milk in the main milk pipe into the milk tank with the aid of the pressurized liquid, wherein the liquid transferring action includes bringing the pressurized liquid supply and the first discharge into liquid connection with the main milk pipe, and breaking a liquid connection of the main milk pipe with the second discharge, allowing an amount of pressurized liquid to flow under pressure from the pressurized liquid supply into the main milk pipe, and breaking the liquid connection between the main milk pipe and the first discharge. Transferring the milk in this way means that it is subjected to less mechanical load and mixed with less air, which benefits the quality. The invention also provides a temporary milk storage vessel and method of this type.

There is provided a method for improving the reliability and performance of a valve device that transitions between the pressure and vacuum phases for the purpose of milking animals. The improvement properly biases the movable parts and reduces physical wear of the movable parts within the valve device while ensuring proper function of said movable parts.

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 system comprising a teat preparation cup coupled to a vacuum pump. A first pressure sensor measures the vacuum level of the vacuum pump. A second pressure sensor measures vacuum level inside the preparation cup. The system further comprises a controller comprising an interface, a memory, and a processor. The processor determines if the vacuum pump has sufficient vacuum level and communicates instructions to induce a partial vacuum in the teat preparation cup. The processor determines if the teat preparation cup has a vacuum level greater than a vacuum threshold value and when this condition is achieved, communicates instructions to initiate a teat preparation cycle comprising allowing fluid flowing from a fluid source container through the teat preparation cup into a fluid disposal container.